OpenCloudOS-Kernel/fs/xfs/libxfs/xfs_defer.c

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// SPDX-License-Identifier: GPL-2.0+
/*
* Copyright (C) 2016 Oracle. All Rights Reserved.
* Author: Darrick J. Wong <darrick.wong@oracle.com>
*/
#include "xfs.h"
#include "xfs_fs.h"
#include "xfs_shared.h"
#include "xfs_format.h"
#include "xfs_log_format.h"
#include "xfs_trans_resv.h"
#include "xfs_mount.h"
#include "xfs_defer.h"
#include "xfs_trans.h"
#include "xfs_buf_item.h"
#include "xfs_inode.h"
#include "xfs_inode_item.h"
#include "xfs_trace.h"
/*
* Deferred Operations in XFS
*
* Due to the way locking rules work in XFS, certain transactions (block
* mapping and unmapping, typically) have permanent reservations so that
* we can roll the transaction to adhere to AG locking order rules and
* to unlock buffers between metadata updates. Prior to rmap/reflink,
* the mapping code had a mechanism to perform these deferrals for
* extents that were going to be freed; this code makes that facility
* more generic.
*
* When adding the reverse mapping and reflink features, it became
* necessary to perform complex remapping multi-transactions to comply
* with AG locking order rules, and to be able to spread a single
* refcount update operation (an operation on an n-block extent can
* update as many as n records!) among multiple transactions. XFS can
* roll a transaction to facilitate this, but using this facility
* requires us to log "intent" items in case log recovery needs to
* redo the operation, and to log "done" items to indicate that redo
* is not necessary.
*
* Deferred work is tracked in xfs_defer_pending items. Each pending
* item tracks one type of deferred work. Incoming work items (which
* have not yet had an intent logged) are attached to a pending item
* on the dop_intake list, where they wait for the caller to finish
* the deferred operations.
*
* Finishing a set of deferred operations is an involved process. To
* start, we define "rolling a deferred-op transaction" as follows:
*
* > For each xfs_defer_pending item on the dop_intake list,
* - Sort the work items in AG order. XFS locking
* order rules require us to lock buffers in AG order.
* - Create a log intent item for that type.
* - Attach it to the pending item.
* - Move the pending item from the dop_intake list to the
* dop_pending list.
* > Roll the transaction.
*
* NOTE: To avoid exceeding the transaction reservation, we limit the
* number of items that we attach to a given xfs_defer_pending.
*
* The actual finishing process looks like this:
*
* > For each xfs_defer_pending in the dop_pending list,
* - Roll the deferred-op transaction as above.
* - Create a log done item for that type, and attach it to the
* log intent item.
* - For each work item attached to the log intent item,
* * Perform the described action.
* * Attach the work item to the log done item.
* * If the result of doing the work was -EAGAIN, ->finish work
* wants a new transaction. See the "Requesting a Fresh
* Transaction while Finishing Deferred Work" section below for
* details.
*
* The key here is that we must log an intent item for all pending
* work items every time we roll the transaction, and that we must log
* a done item as soon as the work is completed. With this mechanism
* we can perform complex remapping operations, chaining intent items
* as needed.
*
* Requesting a Fresh Transaction while Finishing Deferred Work
*
* If ->finish_item decides that it needs a fresh transaction to
* finish the work, it must ask its caller (xfs_defer_finish) for a
* continuation. The most likely cause of this circumstance are the
* refcount adjust functions deciding that they've logged enough items
* to be at risk of exceeding the transaction reservation.
*
* To get a fresh transaction, we want to log the existing log done
* item to prevent the log intent item from replaying, immediately log
* a new log intent item with the unfinished work items, roll the
* transaction, and re-call ->finish_item wherever it left off. The
* log done item and the new log intent item must be in the same
* transaction or atomicity cannot be guaranteed; defer_finish ensures
* that this happens.
*
* This requires some coordination between ->finish_item and
* defer_finish. Upon deciding to request a new transaction,
* ->finish_item should update the current work item to reflect the
* unfinished work. Next, it should reset the log done item's list
* count to the number of items finished, and return -EAGAIN.
* defer_finish sees the -EAGAIN, logs the new log intent item
* with the remaining work items, and leaves the xfs_defer_pending
* item at the head of the dop_work queue. Then it rolls the
* transaction and picks up processing where it left off. It is
* required that ->finish_item must be careful to leave enough
* transaction reservation to fit the new log intent item.
*
* This is an example of remapping the extent (E, E+B) into file X at
* offset A and dealing with the extent (C, C+B) already being mapped
* there:
* +-------------------------------------------------+
* | Unmap file X startblock C offset A length B | t0
* | Intent to reduce refcount for extent (C, B) |
* | Intent to remove rmap (X, C, A, B) |
* | Intent to free extent (D, 1) (bmbt block) |
* | Intent to map (X, A, B) at startblock E |
* +-------------------------------------------------+
* | Map file X startblock E offset A length B | t1
* | Done mapping (X, E, A, B) |
* | Intent to increase refcount for extent (E, B) |
* | Intent to add rmap (X, E, A, B) |
* +-------------------------------------------------+
* | Reduce refcount for extent (C, B) | t2
* | Done reducing refcount for extent (C, 9) |
* | Intent to reduce refcount for extent (C+9, B-9) |
* | (ran out of space after 9 refcount updates) |
* +-------------------------------------------------+
* | Reduce refcount for extent (C+9, B+9) | t3
* | Done reducing refcount for extent (C+9, B-9) |
* | Increase refcount for extent (E, B) |
* | Done increasing refcount for extent (E, B) |
* | Intent to free extent (C, B) |
* | Intent to free extent (F, 1) (refcountbt block) |
* | Intent to remove rmap (F, 1, REFC) |
* +-------------------------------------------------+
* | Remove rmap (X, C, A, B) | t4
* | Done removing rmap (X, C, A, B) |
* | Add rmap (X, E, A, B) |
* | Done adding rmap (X, E, A, B) |
* | Remove rmap (F, 1, REFC) |
* | Done removing rmap (F, 1, REFC) |
* +-------------------------------------------------+
* | Free extent (C, B) | t5
* | Done freeing extent (C, B) |
* | Free extent (D, 1) |
* | Done freeing extent (D, 1) |
* | Free extent (F, 1) |
* | Done freeing extent (F, 1) |
* +-------------------------------------------------+
*
* If we should crash before t2 commits, log recovery replays
* the following intent items:
*
* - Intent to reduce refcount for extent (C, B)
* - Intent to remove rmap (X, C, A, B)
* - Intent to free extent (D, 1) (bmbt block)
* - Intent to increase refcount for extent (E, B)
* - Intent to add rmap (X, E, A, B)
*
* In the process of recovering, it should also generate and take care
* of these intent items:
*
* - Intent to free extent (C, B)
* - Intent to free extent (F, 1) (refcountbt block)
* - Intent to remove rmap (F, 1, REFC)
*
* Note that the continuation requested between t2 and t3 is likely to
* reoccur.
*/
static const struct xfs_defer_op_type *defer_op_types[] = {
[XFS_DEFER_OPS_TYPE_BMAP] = &xfs_bmap_update_defer_type,
[XFS_DEFER_OPS_TYPE_REFCOUNT] = &xfs_refcount_update_defer_type,
[XFS_DEFER_OPS_TYPE_RMAP] = &xfs_rmap_update_defer_type,
[XFS_DEFER_OPS_TYPE_FREE] = &xfs_extent_free_defer_type,
[XFS_DEFER_OPS_TYPE_AGFL_FREE] = &xfs_agfl_free_defer_type,
};
static void
xfs_defer_create_intent(
struct xfs_trans *tp,
struct xfs_defer_pending *dfp,
bool sort)
{
const struct xfs_defer_op_type *ops = defer_op_types[dfp->dfp_type];
dfp->dfp_intent = ops->create_intent(tp, &dfp->dfp_work,
dfp->dfp_count, sort);
}
/*
* For each pending item in the intake list, log its intent item and the
* associated extents, then add the entire intake list to the end of
* the pending list.
*/
STATIC void
xfs_defer_create_intents(
struct xfs_trans *tp)
{
struct xfs_defer_pending *dfp;
list_for_each_entry(dfp, &tp->t_dfops, dfp_list) {
trace_xfs_defer_create_intent(tp->t_mountp, dfp);
xfs_defer_create_intent(tp, dfp, true);
}
}
/* Abort all the intents that were committed. */
STATIC void
xfs_defer_trans_abort(
struct xfs_trans *tp,
struct list_head *dop_pending)
{
struct xfs_defer_pending *dfp;
const struct xfs_defer_op_type *ops;
trace_xfs_defer_trans_abort(tp, _RET_IP_);
/* Abort intent items that don't have a done item. */
list_for_each_entry(dfp, dop_pending, dfp_list) {
ops = defer_op_types[dfp->dfp_type];
trace_xfs_defer_pending_abort(tp->t_mountp, dfp);
if (dfp->dfp_intent && !dfp->dfp_done) {
ops->abort_intent(dfp->dfp_intent);
dfp->dfp_intent = NULL;
}
}
}
/* Roll a transaction so we can do some deferred op processing. */
STATIC int
xfs_defer_trans_roll(
struct xfs_trans **tpp)
{
struct xfs_trans *tp = *tpp;
struct xfs_buf_log_item *bli;
struct xfs_inode_log_item *ili;
struct xfs_log_item *lip;
struct xfs_buf *bplist[XFS_DEFER_OPS_NR_BUFS];
struct xfs_inode *iplist[XFS_DEFER_OPS_NR_INODES];
xfs: use ordered buffers to initialize dquot buffers during quotacheck While QAing the new xfs_repair quotacheck code, I uncovered a quota corruption bug resulting from a bad interaction between dquot buffer initialization and quotacheck. The bug can be reproduced with the following sequence: # mkfs.xfs -f /dev/sdf # mount /dev/sdf /opt -o usrquota # su nobody -s /bin/bash -c 'touch /opt/barf' # sync # xfs_quota -x -c 'report -ahi' /opt User quota on /opt (/dev/sdf) Inodes User ID Used Soft Hard Warn/Grace ---------- --------------------------------- root 3 0 0 00 [------] nobody 1 0 0 00 [------] # xfs_io -x -c 'shutdown' /opt # umount /opt # mount /dev/sdf /opt -o usrquota # touch /opt/man2 # xfs_quota -x -c 'report -ahi' /opt User quota on /opt (/dev/sdf) Inodes User ID Used Soft Hard Warn/Grace ---------- --------------------------------- root 1 0 0 00 [------] nobody 1 0 0 00 [------] # umount /opt Notice how the initial quotacheck set the root dquot icount to 3 (rootino, rbmino, rsumino), but after shutdown -> remount -> recovery, xfs_quota reports that the root dquot has only 1 icount. We haven't deleted anything from the filesystem, which means that quota is now under-counting. This behavior is not limited to icount or the root dquot, but this is the shortest reproducer. I traced the cause of this discrepancy to the way that we handle ondisk dquot updates during quotacheck vs. regular fs activity. Normally, when we allocate a disk block for a dquot, we log the buffer as a regular (dquot) buffer. Subsequent updates to the dquots backed by that block are done via separate dquot log item updates, which means that they depend on the logged buffer update being written to disk before the dquot items. Because individual dquots have their own LSN fields, that initial dquot buffer must always be recovered. However, the story changes for quotacheck, which can cause dquot block allocations but persists the final dquot counter values via a delwri list. Because recovery doesn't gate dquot buffer replay on an LSN, this means that the initial dquot buffer can be replayed over the (newer) contents that were delwritten at the end of quotacheck. In effect, this re-initializes the dquot counters after they've been updated. If the log does not contain any other dquot items to recover, the obsolete dquot contents will not be corrected by log recovery. Because quotacheck uses a transaction to log the setting of the CHKD flags in the superblock, we skip quotacheck during the second mount call, which allows the incorrect icount to remain. Fix this by changing the ondisk dquot initialization function to use ordered buffers to write out fresh dquot blocks if it detects that we're running quotacheck. If the system goes down before quotacheck can complete, the CHKD flags will not be set in the superblock and the next mount will run quotacheck again, which can fix uninitialized dquot buffers. This requires amending the defer code to maintaine ordered buffer state across defer rolls for the sake of the dquot allocation code. For regular operations we preserve the current behavior since the dquot items require properly initialized ondisk dquot records. Signed-off-by: Darrick J. Wong <darrick.wong@oracle.com> Reviewed-by: Brian Foster <bfoster@redhat.com> Reviewed-by: Christoph Hellwig <hch@lst.de>
2020-05-14 06:33:27 +08:00
unsigned int ordered = 0; /* bitmap */
int bpcount = 0, ipcount = 0;
int i;
int error;
xfs: use ordered buffers to initialize dquot buffers during quotacheck While QAing the new xfs_repair quotacheck code, I uncovered a quota corruption bug resulting from a bad interaction between dquot buffer initialization and quotacheck. The bug can be reproduced with the following sequence: # mkfs.xfs -f /dev/sdf # mount /dev/sdf /opt -o usrquota # su nobody -s /bin/bash -c 'touch /opt/barf' # sync # xfs_quota -x -c 'report -ahi' /opt User quota on /opt (/dev/sdf) Inodes User ID Used Soft Hard Warn/Grace ---------- --------------------------------- root 3 0 0 00 [------] nobody 1 0 0 00 [------] # xfs_io -x -c 'shutdown' /opt # umount /opt # mount /dev/sdf /opt -o usrquota # touch /opt/man2 # xfs_quota -x -c 'report -ahi' /opt User quota on /opt (/dev/sdf) Inodes User ID Used Soft Hard Warn/Grace ---------- --------------------------------- root 1 0 0 00 [------] nobody 1 0 0 00 [------] # umount /opt Notice how the initial quotacheck set the root dquot icount to 3 (rootino, rbmino, rsumino), but after shutdown -> remount -> recovery, xfs_quota reports that the root dquot has only 1 icount. We haven't deleted anything from the filesystem, which means that quota is now under-counting. This behavior is not limited to icount or the root dquot, but this is the shortest reproducer. I traced the cause of this discrepancy to the way that we handle ondisk dquot updates during quotacheck vs. regular fs activity. Normally, when we allocate a disk block for a dquot, we log the buffer as a regular (dquot) buffer. Subsequent updates to the dquots backed by that block are done via separate dquot log item updates, which means that they depend on the logged buffer update being written to disk before the dquot items. Because individual dquots have their own LSN fields, that initial dquot buffer must always be recovered. However, the story changes for quotacheck, which can cause dquot block allocations but persists the final dquot counter values via a delwri list. Because recovery doesn't gate dquot buffer replay on an LSN, this means that the initial dquot buffer can be replayed over the (newer) contents that were delwritten at the end of quotacheck. In effect, this re-initializes the dquot counters after they've been updated. If the log does not contain any other dquot items to recover, the obsolete dquot contents will not be corrected by log recovery. Because quotacheck uses a transaction to log the setting of the CHKD flags in the superblock, we skip quotacheck during the second mount call, which allows the incorrect icount to remain. Fix this by changing the ondisk dquot initialization function to use ordered buffers to write out fresh dquot blocks if it detects that we're running quotacheck. If the system goes down before quotacheck can complete, the CHKD flags will not be set in the superblock and the next mount will run quotacheck again, which can fix uninitialized dquot buffers. This requires amending the defer code to maintaine ordered buffer state across defer rolls for the sake of the dquot allocation code. For regular operations we preserve the current behavior since the dquot items require properly initialized ondisk dquot records. Signed-off-by: Darrick J. Wong <darrick.wong@oracle.com> Reviewed-by: Brian Foster <bfoster@redhat.com> Reviewed-by: Christoph Hellwig <hch@lst.de>
2020-05-14 06:33:27 +08:00
BUILD_BUG_ON(NBBY * sizeof(ordered) < XFS_DEFER_OPS_NR_BUFS);
list_for_each_entry(lip, &tp->t_items, li_trans) {
switch (lip->li_type) {
case XFS_LI_BUF:
bli = container_of(lip, struct xfs_buf_log_item,
bli_item);
if (bli->bli_flags & XFS_BLI_HOLD) {
if (bpcount >= XFS_DEFER_OPS_NR_BUFS) {
ASSERT(0);
return -EFSCORRUPTED;
}
xfs: use ordered buffers to initialize dquot buffers during quotacheck While QAing the new xfs_repair quotacheck code, I uncovered a quota corruption bug resulting from a bad interaction between dquot buffer initialization and quotacheck. The bug can be reproduced with the following sequence: # mkfs.xfs -f /dev/sdf # mount /dev/sdf /opt -o usrquota # su nobody -s /bin/bash -c 'touch /opt/barf' # sync # xfs_quota -x -c 'report -ahi' /opt User quota on /opt (/dev/sdf) Inodes User ID Used Soft Hard Warn/Grace ---------- --------------------------------- root 3 0 0 00 [------] nobody 1 0 0 00 [------] # xfs_io -x -c 'shutdown' /opt # umount /opt # mount /dev/sdf /opt -o usrquota # touch /opt/man2 # xfs_quota -x -c 'report -ahi' /opt User quota on /opt (/dev/sdf) Inodes User ID Used Soft Hard Warn/Grace ---------- --------------------------------- root 1 0 0 00 [------] nobody 1 0 0 00 [------] # umount /opt Notice how the initial quotacheck set the root dquot icount to 3 (rootino, rbmino, rsumino), but after shutdown -> remount -> recovery, xfs_quota reports that the root dquot has only 1 icount. We haven't deleted anything from the filesystem, which means that quota is now under-counting. This behavior is not limited to icount or the root dquot, but this is the shortest reproducer. I traced the cause of this discrepancy to the way that we handle ondisk dquot updates during quotacheck vs. regular fs activity. Normally, when we allocate a disk block for a dquot, we log the buffer as a regular (dquot) buffer. Subsequent updates to the dquots backed by that block are done via separate dquot log item updates, which means that they depend on the logged buffer update being written to disk before the dquot items. Because individual dquots have their own LSN fields, that initial dquot buffer must always be recovered. However, the story changes for quotacheck, which can cause dquot block allocations but persists the final dquot counter values via a delwri list. Because recovery doesn't gate dquot buffer replay on an LSN, this means that the initial dquot buffer can be replayed over the (newer) contents that were delwritten at the end of quotacheck. In effect, this re-initializes the dquot counters after they've been updated. If the log does not contain any other dquot items to recover, the obsolete dquot contents will not be corrected by log recovery. Because quotacheck uses a transaction to log the setting of the CHKD flags in the superblock, we skip quotacheck during the second mount call, which allows the incorrect icount to remain. Fix this by changing the ondisk dquot initialization function to use ordered buffers to write out fresh dquot blocks if it detects that we're running quotacheck. If the system goes down before quotacheck can complete, the CHKD flags will not be set in the superblock and the next mount will run quotacheck again, which can fix uninitialized dquot buffers. This requires amending the defer code to maintaine ordered buffer state across defer rolls for the sake of the dquot allocation code. For regular operations we preserve the current behavior since the dquot items require properly initialized ondisk dquot records. Signed-off-by: Darrick J. Wong <darrick.wong@oracle.com> Reviewed-by: Brian Foster <bfoster@redhat.com> Reviewed-by: Christoph Hellwig <hch@lst.de>
2020-05-14 06:33:27 +08:00
if (bli->bli_flags & XFS_BLI_ORDERED)
ordered |= (1U << bpcount);
else
xfs_trans_dirty_buf(tp, bli->bli_buf);
bplist[bpcount++] = bli->bli_buf;
}
break;
case XFS_LI_INODE:
ili = container_of(lip, struct xfs_inode_log_item,
ili_item);
if (ili->ili_lock_flags == 0) {
if (ipcount >= XFS_DEFER_OPS_NR_INODES) {
ASSERT(0);
return -EFSCORRUPTED;
}
xfs_trans_log_inode(tp, ili->ili_inode,
XFS_ILOG_CORE);
iplist[ipcount++] = ili->ili_inode;
}
break;
default:
break;
}
}
trace_xfs_defer_trans_roll(tp, _RET_IP_);
/*
* Roll the transaction. Rolling always given a new transaction (even
* if committing the old one fails!) to hand back to the caller, so we
* join the held resources to the new transaction so that we always
* return with the held resources joined to @tpp, no matter what
* happened.
*/
error = xfs_trans_roll(tpp);
tp = *tpp;
/* Rejoin the joined inodes. */
for (i = 0; i < ipcount; i++)
xfs_trans_ijoin(tp, iplist[i], 0);
/* Rejoin the buffers and dirty them so the log moves forward. */
for (i = 0; i < bpcount; i++) {
xfs_trans_bjoin(tp, bplist[i]);
xfs: use ordered buffers to initialize dquot buffers during quotacheck While QAing the new xfs_repair quotacheck code, I uncovered a quota corruption bug resulting from a bad interaction between dquot buffer initialization and quotacheck. The bug can be reproduced with the following sequence: # mkfs.xfs -f /dev/sdf # mount /dev/sdf /opt -o usrquota # su nobody -s /bin/bash -c 'touch /opt/barf' # sync # xfs_quota -x -c 'report -ahi' /opt User quota on /opt (/dev/sdf) Inodes User ID Used Soft Hard Warn/Grace ---------- --------------------------------- root 3 0 0 00 [------] nobody 1 0 0 00 [------] # xfs_io -x -c 'shutdown' /opt # umount /opt # mount /dev/sdf /opt -o usrquota # touch /opt/man2 # xfs_quota -x -c 'report -ahi' /opt User quota on /opt (/dev/sdf) Inodes User ID Used Soft Hard Warn/Grace ---------- --------------------------------- root 1 0 0 00 [------] nobody 1 0 0 00 [------] # umount /opt Notice how the initial quotacheck set the root dquot icount to 3 (rootino, rbmino, rsumino), but after shutdown -> remount -> recovery, xfs_quota reports that the root dquot has only 1 icount. We haven't deleted anything from the filesystem, which means that quota is now under-counting. This behavior is not limited to icount or the root dquot, but this is the shortest reproducer. I traced the cause of this discrepancy to the way that we handle ondisk dquot updates during quotacheck vs. regular fs activity. Normally, when we allocate a disk block for a dquot, we log the buffer as a regular (dquot) buffer. Subsequent updates to the dquots backed by that block are done via separate dquot log item updates, which means that they depend on the logged buffer update being written to disk before the dquot items. Because individual dquots have their own LSN fields, that initial dquot buffer must always be recovered. However, the story changes for quotacheck, which can cause dquot block allocations but persists the final dquot counter values via a delwri list. Because recovery doesn't gate dquot buffer replay on an LSN, this means that the initial dquot buffer can be replayed over the (newer) contents that were delwritten at the end of quotacheck. In effect, this re-initializes the dquot counters after they've been updated. If the log does not contain any other dquot items to recover, the obsolete dquot contents will not be corrected by log recovery. Because quotacheck uses a transaction to log the setting of the CHKD flags in the superblock, we skip quotacheck during the second mount call, which allows the incorrect icount to remain. Fix this by changing the ondisk dquot initialization function to use ordered buffers to write out fresh dquot blocks if it detects that we're running quotacheck. If the system goes down before quotacheck can complete, the CHKD flags will not be set in the superblock and the next mount will run quotacheck again, which can fix uninitialized dquot buffers. This requires amending the defer code to maintaine ordered buffer state across defer rolls for the sake of the dquot allocation code. For regular operations we preserve the current behavior since the dquot items require properly initialized ondisk dquot records. Signed-off-by: Darrick J. Wong <darrick.wong@oracle.com> Reviewed-by: Brian Foster <bfoster@redhat.com> Reviewed-by: Christoph Hellwig <hch@lst.de>
2020-05-14 06:33:27 +08:00
if (ordered & (1U << i))
xfs_trans_ordered_buf(tp, bplist[i]);
xfs_trans_bhold(tp, bplist[i]);
}
if (error)
trace_xfs_defer_trans_roll_error(tp, error);
return error;
}
/*
* Reset an already used dfops after finish.
*/
static void
xfs_defer_reset(
struct xfs_trans *tp)
{
ASSERT(list_empty(&tp->t_dfops));
/*
* Low mode state transfers across transaction rolls to mirror dfops
* lifetime. Clear it now that dfops is reset.
*/
tp->t_flags &= ~XFS_TRANS_LOWMODE;
}
/*
* Free up any items left in the list.
*/
static void
xfs_defer_cancel_list(
struct xfs_mount *mp,
struct list_head *dop_list)
{
struct xfs_defer_pending *dfp;
struct xfs_defer_pending *pli;
struct list_head *pwi;
struct list_head *n;
const struct xfs_defer_op_type *ops;
/*
* Free the pending items. Caller should already have arranged
* for the intent items to be released.
*/
list_for_each_entry_safe(dfp, pli, dop_list, dfp_list) {
ops = defer_op_types[dfp->dfp_type];
trace_xfs_defer_cancel_list(mp, dfp);
list_del(&dfp->dfp_list);
list_for_each_safe(pwi, n, &dfp->dfp_work) {
list_del(pwi);
dfp->dfp_count--;
ops->cancel_item(pwi);
}
ASSERT(dfp->dfp_count == 0);
kmem_free(dfp);
}
}
/*
* Log an intent-done item for the first pending intent, and finish the work
* items.
*/
static int
xfs_defer_finish_one(
struct xfs_trans *tp,
struct xfs_defer_pending *dfp)
{
const struct xfs_defer_op_type *ops = defer_op_types[dfp->dfp_type];
struct xfs_btree_cur *state = NULL;
struct list_head *li, *n;
int error;
trace_xfs_defer_pending_finish(tp->t_mountp, dfp);
dfp->dfp_done = ops->create_done(tp, dfp->dfp_intent, dfp->dfp_count);
list_for_each_safe(li, n, &dfp->dfp_work) {
list_del(li);
dfp->dfp_count--;
error = ops->finish_item(tp, dfp->dfp_done, li, &state);
if (error == -EAGAIN) {
/*
* Caller wants a fresh transaction; put the work item
* back on the list and log a new log intent item to
* replace the old one. See "Requesting a Fresh
* Transaction while Finishing Deferred Work" above.
*/
list_add(li, &dfp->dfp_work);
dfp->dfp_count++;
dfp->dfp_done = NULL;
xfs_defer_create_intent(tp, dfp, false);
}
if (error)
goto out;
}
/* Done with the dfp, free it. */
list_del(&dfp->dfp_list);
kmem_free(dfp);
out:
if (ops->finish_cleanup)
ops->finish_cleanup(tp, state, error);
return error;
}
/*
* Finish all the pending work. This involves logging intent items for
* any work items that wandered in since the last transaction roll (if
* one has even happened), rolling the transaction, and finishing the
* work items in the first item on the logged-and-pending list.
*
* If an inode is provided, relog it to the new transaction.
*/
int
xfs_defer_finish_noroll(
struct xfs_trans **tp)
{
struct xfs_defer_pending *dfp;
int error = 0;
LIST_HEAD(dop_pending);
ASSERT((*tp)->t_flags & XFS_TRANS_PERM_LOG_RES);
trace_xfs_defer_finish(*tp, _RET_IP_);
/* Until we run out of pending work to finish... */
while (!list_empty(&dop_pending) || !list_empty(&(*tp)->t_dfops)) {
xfs_defer_create_intents(*tp);
list_splice_tail_init(&(*tp)->t_dfops, &dop_pending);
error = xfs_defer_trans_roll(tp);
if (error)
goto out_shutdown;
dfp = list_first_entry(&dop_pending, struct xfs_defer_pending,
dfp_list);
error = xfs_defer_finish_one(*tp, dfp);
if (error && error != -EAGAIN)
goto out_shutdown;
}
trace_xfs_defer_finish_done(*tp, _RET_IP_);
return 0;
out_shutdown:
xfs_defer_trans_abort(*tp, &dop_pending);
xfs_force_shutdown((*tp)->t_mountp, SHUTDOWN_CORRUPT_INCORE);
trace_xfs_defer_finish_error(*tp, error);
xfs_defer_cancel_list((*tp)->t_mountp, &dop_pending);
xfs_defer_cancel(*tp);
return error;
}
int
xfs_defer_finish(
struct xfs_trans **tp)
{
int error;
/*
* Finish and roll the transaction once more to avoid returning to the
* caller with a dirty transaction.
*/
error = xfs_defer_finish_noroll(tp);
if (error)
return error;
if ((*tp)->t_flags & XFS_TRANS_DIRTY) {
error = xfs_defer_trans_roll(tp);
if (error) {
xfs_force_shutdown((*tp)->t_mountp,
SHUTDOWN_CORRUPT_INCORE);
return error;
}
}
xfs_defer_reset(*tp);
return 0;
}
void
xfs_defer_cancel(
struct xfs_trans *tp)
{
struct xfs_mount *mp = tp->t_mountp;
trace_xfs_defer_cancel(tp, _RET_IP_);
xfs_defer_cancel_list(mp, &tp->t_dfops);
}
/* Add an item for later deferred processing. */
void
xfs_defer_add(
struct xfs_trans *tp,
enum xfs_defer_ops_type type,
struct list_head *li)
{
struct xfs_defer_pending *dfp = NULL;
const struct xfs_defer_op_type *ops;
ASSERT(tp->t_flags & XFS_TRANS_PERM_LOG_RES);
BUILD_BUG_ON(ARRAY_SIZE(defer_op_types) != XFS_DEFER_OPS_TYPE_MAX);
/*
* Add the item to a pending item at the end of the intake list.
* If the last pending item has the same type, reuse it. Else,
* create a new pending item at the end of the intake list.
*/
if (!list_empty(&tp->t_dfops)) {
dfp = list_last_entry(&tp->t_dfops,
struct xfs_defer_pending, dfp_list);
ops = defer_op_types[dfp->dfp_type];
if (dfp->dfp_type != type ||
(ops->max_items && dfp->dfp_count >= ops->max_items))
dfp = NULL;
}
if (!dfp) {
dfp = kmem_alloc(sizeof(struct xfs_defer_pending),
KM_NOFS);
dfp->dfp_type = type;
dfp->dfp_intent = NULL;
dfp->dfp_done = NULL;
dfp->dfp_count = 0;
INIT_LIST_HEAD(&dfp->dfp_work);
list_add_tail(&dfp->dfp_list, &tp->t_dfops);
}
list_add_tail(li, &dfp->dfp_work);
dfp->dfp_count++;
}
xfs: support embedded dfops in transaction The dfops structure used by multi-transaction operations is typically stored on the stack and carried around by the associated transaction. The lifecycle of dfops does not quite match that of the transaction, but they are tightly related in that the former depends on the latter. The relationship of these objects is tight enough that we can avoid the cumbersome boilerplate code required in most cases to manage them separately by just embedding an xfs_defer_ops in the transaction itself. This means that a transaction allocation returns with an initialized dfops, a transaction commit finishes pending deferred items before the tx commit, a transaction cancel cancels the dfops before the transaction and a transaction dup operation transfers the current dfops state to the new transaction. The dup operation is slightly complicated by the fact that we can no longer just copy a dfops pointer from the old transaction to the new transaction. This is solved through a dfops move helper that transfers the pending items and other dfops state across the transactions. This also requires that transaction rolling code always refer to the transaction for the current dfops reference. Finally, to facilitate incremental conversion to the internal dfops and continue to support the current external dfops mode of operation, create the new ->t_dfops_internal field with a layer of indirection. On allocation, ->t_dfops points to the internal dfops. This state is overridden by callers who re-init a local dfops on the transaction. Once ->t_dfops is overridden, the external dfops reference is maintained as the transaction rolls. This patch adds the fundamental ability to support an internal dfops. All codepaths that perform deferred processing continue to override the internal dfops until they are converted over in subsequent patches. Signed-off-by: Brian Foster <bfoster@redhat.com> Reviewed-by: Bill O'Donnell <billodo@redhat.com> Reviewed-by: Christoph Hellwig <hch@lst.de> Reviewed-by: Darrick J. Wong <darrick.wong@oracle.com> Signed-off-by: Darrick J. Wong <darrick.wong@oracle.com>
2018-07-25 04:43:11 +08:00
/*
* Move deferred ops from one transaction to another and reset the source to
* initial state. This is primarily used to carry state forward across
* transaction rolls with pending dfops.
xfs: support embedded dfops in transaction The dfops structure used by multi-transaction operations is typically stored on the stack and carried around by the associated transaction. The lifecycle of dfops does not quite match that of the transaction, but they are tightly related in that the former depends on the latter. The relationship of these objects is tight enough that we can avoid the cumbersome boilerplate code required in most cases to manage them separately by just embedding an xfs_defer_ops in the transaction itself. This means that a transaction allocation returns with an initialized dfops, a transaction commit finishes pending deferred items before the tx commit, a transaction cancel cancels the dfops before the transaction and a transaction dup operation transfers the current dfops state to the new transaction. The dup operation is slightly complicated by the fact that we can no longer just copy a dfops pointer from the old transaction to the new transaction. This is solved through a dfops move helper that transfers the pending items and other dfops state across the transactions. This also requires that transaction rolling code always refer to the transaction for the current dfops reference. Finally, to facilitate incremental conversion to the internal dfops and continue to support the current external dfops mode of operation, create the new ->t_dfops_internal field with a layer of indirection. On allocation, ->t_dfops points to the internal dfops. This state is overridden by callers who re-init a local dfops on the transaction. Once ->t_dfops is overridden, the external dfops reference is maintained as the transaction rolls. This patch adds the fundamental ability to support an internal dfops. All codepaths that perform deferred processing continue to override the internal dfops until they are converted over in subsequent patches. Signed-off-by: Brian Foster <bfoster@redhat.com> Reviewed-by: Bill O'Donnell <billodo@redhat.com> Reviewed-by: Christoph Hellwig <hch@lst.de> Reviewed-by: Darrick J. Wong <darrick.wong@oracle.com> Signed-off-by: Darrick J. Wong <darrick.wong@oracle.com>
2018-07-25 04:43:11 +08:00
*/
void
xfs_defer_move(
struct xfs_trans *dtp,
struct xfs_trans *stp)
xfs: support embedded dfops in transaction The dfops structure used by multi-transaction operations is typically stored on the stack and carried around by the associated transaction. The lifecycle of dfops does not quite match that of the transaction, but they are tightly related in that the former depends on the latter. The relationship of these objects is tight enough that we can avoid the cumbersome boilerplate code required in most cases to manage them separately by just embedding an xfs_defer_ops in the transaction itself. This means that a transaction allocation returns with an initialized dfops, a transaction commit finishes pending deferred items before the tx commit, a transaction cancel cancels the dfops before the transaction and a transaction dup operation transfers the current dfops state to the new transaction. The dup operation is slightly complicated by the fact that we can no longer just copy a dfops pointer from the old transaction to the new transaction. This is solved through a dfops move helper that transfers the pending items and other dfops state across the transactions. This also requires that transaction rolling code always refer to the transaction for the current dfops reference. Finally, to facilitate incremental conversion to the internal dfops and continue to support the current external dfops mode of operation, create the new ->t_dfops_internal field with a layer of indirection. On allocation, ->t_dfops points to the internal dfops. This state is overridden by callers who re-init a local dfops on the transaction. Once ->t_dfops is overridden, the external dfops reference is maintained as the transaction rolls. This patch adds the fundamental ability to support an internal dfops. All codepaths that perform deferred processing continue to override the internal dfops until they are converted over in subsequent patches. Signed-off-by: Brian Foster <bfoster@redhat.com> Reviewed-by: Bill O'Donnell <billodo@redhat.com> Reviewed-by: Christoph Hellwig <hch@lst.de> Reviewed-by: Darrick J. Wong <darrick.wong@oracle.com> Signed-off-by: Darrick J. Wong <darrick.wong@oracle.com>
2018-07-25 04:43:11 +08:00
{
list_splice_init(&stp->t_dfops, &dtp->t_dfops);
xfs: support embedded dfops in transaction The dfops structure used by multi-transaction operations is typically stored on the stack and carried around by the associated transaction. The lifecycle of dfops does not quite match that of the transaction, but they are tightly related in that the former depends on the latter. The relationship of these objects is tight enough that we can avoid the cumbersome boilerplate code required in most cases to manage them separately by just embedding an xfs_defer_ops in the transaction itself. This means that a transaction allocation returns with an initialized dfops, a transaction commit finishes pending deferred items before the tx commit, a transaction cancel cancels the dfops before the transaction and a transaction dup operation transfers the current dfops state to the new transaction. The dup operation is slightly complicated by the fact that we can no longer just copy a dfops pointer from the old transaction to the new transaction. This is solved through a dfops move helper that transfers the pending items and other dfops state across the transactions. This also requires that transaction rolling code always refer to the transaction for the current dfops reference. Finally, to facilitate incremental conversion to the internal dfops and continue to support the current external dfops mode of operation, create the new ->t_dfops_internal field with a layer of indirection. On allocation, ->t_dfops points to the internal dfops. This state is overridden by callers who re-init a local dfops on the transaction. Once ->t_dfops is overridden, the external dfops reference is maintained as the transaction rolls. This patch adds the fundamental ability to support an internal dfops. All codepaths that perform deferred processing continue to override the internal dfops until they are converted over in subsequent patches. Signed-off-by: Brian Foster <bfoster@redhat.com> Reviewed-by: Bill O'Donnell <billodo@redhat.com> Reviewed-by: Christoph Hellwig <hch@lst.de> Reviewed-by: Darrick J. Wong <darrick.wong@oracle.com> Signed-off-by: Darrick J. Wong <darrick.wong@oracle.com>
2018-07-25 04:43:11 +08:00
/*
* Low free space mode was historically controlled by a dfops field.
* This meant that low mode state potentially carried across multiple
* transaction rolls. Transfer low mode on a dfops move to preserve
* that behavior.
*/
dtp->t_flags |= (stp->t_flags & XFS_TRANS_LOWMODE);
xfs: support embedded dfops in transaction The dfops structure used by multi-transaction operations is typically stored on the stack and carried around by the associated transaction. The lifecycle of dfops does not quite match that of the transaction, but they are tightly related in that the former depends on the latter. The relationship of these objects is tight enough that we can avoid the cumbersome boilerplate code required in most cases to manage them separately by just embedding an xfs_defer_ops in the transaction itself. This means that a transaction allocation returns with an initialized dfops, a transaction commit finishes pending deferred items before the tx commit, a transaction cancel cancels the dfops before the transaction and a transaction dup operation transfers the current dfops state to the new transaction. The dup operation is slightly complicated by the fact that we can no longer just copy a dfops pointer from the old transaction to the new transaction. This is solved through a dfops move helper that transfers the pending items and other dfops state across the transactions. This also requires that transaction rolling code always refer to the transaction for the current dfops reference. Finally, to facilitate incremental conversion to the internal dfops and continue to support the current external dfops mode of operation, create the new ->t_dfops_internal field with a layer of indirection. On allocation, ->t_dfops points to the internal dfops. This state is overridden by callers who re-init a local dfops on the transaction. Once ->t_dfops is overridden, the external dfops reference is maintained as the transaction rolls. This patch adds the fundamental ability to support an internal dfops. All codepaths that perform deferred processing continue to override the internal dfops until they are converted over in subsequent patches. Signed-off-by: Brian Foster <bfoster@redhat.com> Reviewed-by: Bill O'Donnell <billodo@redhat.com> Reviewed-by: Christoph Hellwig <hch@lst.de> Reviewed-by: Darrick J. Wong <darrick.wong@oracle.com> Signed-off-by: Darrick J. Wong <darrick.wong@oracle.com>
2018-07-25 04:43:11 +08:00
xfs_defer_reset(stp);
xfs: support embedded dfops in transaction The dfops structure used by multi-transaction operations is typically stored on the stack and carried around by the associated transaction. The lifecycle of dfops does not quite match that of the transaction, but they are tightly related in that the former depends on the latter. The relationship of these objects is tight enough that we can avoid the cumbersome boilerplate code required in most cases to manage them separately by just embedding an xfs_defer_ops in the transaction itself. This means that a transaction allocation returns with an initialized dfops, a transaction commit finishes pending deferred items before the tx commit, a transaction cancel cancels the dfops before the transaction and a transaction dup operation transfers the current dfops state to the new transaction. The dup operation is slightly complicated by the fact that we can no longer just copy a dfops pointer from the old transaction to the new transaction. This is solved through a dfops move helper that transfers the pending items and other dfops state across the transactions. This also requires that transaction rolling code always refer to the transaction for the current dfops reference. Finally, to facilitate incremental conversion to the internal dfops and continue to support the current external dfops mode of operation, create the new ->t_dfops_internal field with a layer of indirection. On allocation, ->t_dfops points to the internal dfops. This state is overridden by callers who re-init a local dfops on the transaction. Once ->t_dfops is overridden, the external dfops reference is maintained as the transaction rolls. This patch adds the fundamental ability to support an internal dfops. All codepaths that perform deferred processing continue to override the internal dfops until they are converted over in subsequent patches. Signed-off-by: Brian Foster <bfoster@redhat.com> Reviewed-by: Bill O'Donnell <billodo@redhat.com> Reviewed-by: Christoph Hellwig <hch@lst.de> Reviewed-by: Darrick J. Wong <darrick.wong@oracle.com> Signed-off-by: Darrick J. Wong <darrick.wong@oracle.com>
2018-07-25 04:43:11 +08:00
}