Reliability and the Write-Ahead Log
This chapter explains how to control the reliability of
PostgreSQL, including details about the
Write-Ahead Log.
Reliability
Reliability is an important property of any serious database
system, and PostgreSQL does everything possible to
guarantee reliable operation. One aspect of reliable operation is
that all data recorded by a committed transaction should be stored
in a nonvolatile area that is safe from power loss, operating
system failure, and hardware failure (except failure of the
nonvolatile area itself, of course). Successfully writing the data
to the computer's permanent storage (disk drive or equivalent)
ordinarily meets this requirement. In fact, even if a computer is
fatally damaged, if the disk drives survive they can be moved to
another computer with similar hardware and all committed
transactions will remain intact.
While forcing data to the disk platters periodically might seem like
a simple operation, it is not. Because disk drives are dramatically
slower than main memory and CPUs, several layers of caching exist
between the computer's main memory and the disk platters.
First, there is the operating system's buffer cache, which caches
frequently requested disk blocks and combines disk writes. Fortunately,
all operating systems give applications a way to force writes from
the buffer cache to disk, and PostgreSQL uses those
features. (See the parameter
to adjust how this is done.)
Next, there might be a cache in the disk drive controller; this is
particularly common on RAID controller cards. Some of
these caches are write-through, meaning writes are sent
to the drive as soon as they arrive. Others are
write-back, meaning data is sent to the drive at
some later time. Such caches can be a reliability hazard because the
memory in the disk controller cache is volatile, and will lose its
contents in a power failure. Better controller cards have
battery-backup units (BBUs), meaning
the card has a battery that
maintains power to the cache in case of system power loss. After power
is restored the data will be written to the disk drives.
And finally, most disk drives have caches. Some are write-through
while some are write-back, and the same concerns about data loss
exist for write-back drive caches as for disk controller
caches. Consumer-grade IDE and SATA drives are particularly likely
to have write-back caches that will not survive a power failure. Many
solid-state drives (SSD) also have volatile write-back caches.
These caches can typically be disabled; however, the method for doing
this varies by operating system and drive type:
On Linux, IDE and SATA drives can be queried using
hdparm -I; write caching is enabled if there is
a * next to Write cache. hdparm -W 0
can be used to turn off write caching. SCSI drives can be queried
using sdparm.
Use sdparm --get=WCE to check
whether the write cache is enabled and sdparm --clear=WCE
to disable it.
On FreeBSD, IDE drives can be queried using
camcontrol identify and write caching turned off using
hw.ata.wc=0 in /boot/loader.conf;
SCSI drives can be queried using camcontrol identify,
and the write cache both queried and changed using
sdparm when available.
On Solaris, the disk write cache is controlled by
format -e.
(The Solaris ZFS file system is safe with disk write-cache
enabled because it issues its own disk cache flush commands.)
On Windows, if wal_sync_method is
open_datasync (the default), write caching can be disabled
by unchecking My Computer\Open\disk drive\Properties\Hardware\Properties\Policies\Enable write caching on the disk.
Alternatively, set wal_sync_method to
fdatasync (NTFS only), fsync or
fsync_writethrough, which prevent
write caching.
On macOS, write caching can be prevented by
setting wal_sync_method to fsync_writethrough.
Recent SATA drives (those following ATAPI-6 or later)
offer a drive cache flush command (FLUSH CACHE EXT),
while SCSI drives have long supported a similar command
SYNCHRONIZE CACHE. These commands are not directly
accessible to PostgreSQL, but some file systems
(e.g., ZFS, ext4) can use them to flush
data to the platters on write-back-enabled drives. Unfortunately, such
file systems behave suboptimally when combined with battery-backup unit
(BBU) disk controllers. In such setups, the synchronize
command forces all data from the controller cache to the disks,
eliminating much of the benefit of the BBU. You can run the
program to see
if you are affected. If you are affected, the performance benefits
of the BBU can be regained by turning off write barriers in
the file system or reconfiguring the disk controller, if that is
an option. If write barriers are turned off, make sure the battery
remains functional; a faulty battery can potentially lead to data loss.
Hopefully file system and disk controller designers will eventually
address this suboptimal behavior.
When the operating system sends a write request to the storage hardware,
there is little it can do to make sure the data has arrived at a truly
non-volatile storage area. Rather, it is the
administrator's responsibility to make certain that all storage components
ensure integrity for both data and file-system metadata.
Avoid disk controllers that have non-battery-backed write caches.
At the drive level, disable write-back caching if the
drive cannot guarantee the data will be written before shutdown.
If you use SSDs, be aware that many of these do not honor cache flush
commands by default.
You can test for reliable I/O subsystem behavior using diskchecker.pl.
Another risk of data loss is posed by the disk platter write
operations themselves. Disk platters are divided into sectors,
commonly 512 bytes each. Every physical read or write operation
processes a whole sector.
When a write request arrives at the drive, it might be for some multiple
of 512 bytes (PostgreSQL typically writes 8192 bytes, or
16 sectors, at a time), and the process of writing could fail due
to power loss at any time, meaning some of the 512-byte sectors were
written while others were not. To guard against such failures,
PostgreSQL periodically writes full page images to
permanent WAL storage before modifying the actual page on
disk. By doing this, during crash recovery PostgreSQL can
restore partially-written pages from WAL. If you have file-system software
that prevents partial page writes (e.g., ZFS), you can turn off
this page imaging by turning off the parameter. Battery-Backed Unit
(BBU) disk controllers do not prevent partial page writes unless
they guarantee that data is written to the BBU as full (8kB) pages.
PostgreSQL also protects against some kinds of data corruption
on storage devices that may occur because of hardware errors or media failure over time,
such as reading/writing garbage data.
Each individual record in a WAL file is protected by a CRC-32 (32-bit) check
that allows us to tell if record contents are correct. The CRC value
is set when we write each WAL record and checked during crash recovery,
archive recovery and replication.
Data pages are not currently checksummed by default, though full page images
recorded in WAL records will be protected; see initdb
for details about enabling data checksums.
Internal data structures such as pg_xact, pg_subtrans, pg_multixact,
pg_serial, pg_notify, pg_stat, pg_snapshots are not directly
checksummed, nor are pages protected by full page writes. However, where
such data structures are persistent, WAL records are written that allow
recent changes to be accurately rebuilt at crash recovery and those
WAL records are protected as discussed above.
Individual state files in pg_twophase are protected by CRC-32.
Temporary data files used in larger SQL queries for sorts,
materializations and intermediate results are not currently checksummed,
nor will WAL records be written for changes to those files.
PostgreSQL does not protect against correctable memory errors
and it is assumed you will operate using RAM that uses industry standard
Error Correcting Codes (ECC) or better protection.
Data Checksumschecksums
By default, data pages are not protected by checksums, but this can
optionally be enabled for a cluster. When enabled, each data page includes
a checksum that is updated when the page is written and verified each time
the page is read. Only data pages are protected by checksums; internal data
structures and temporary files are not.
Checksums are normally enabled when the cluster is initialized using initdb.
They can also be enabled or disabled at a later time as an offline
operation. Data checksums are enabled or disabled at the full cluster
level, and cannot be specified individually for databases or tables.
The current state of checksums in the cluster can be verified by viewing the
value of the read-only configuration variable by issuing the command SHOW
data_checksums.
When attempting to recover from page corruptions, it may be necessary to
bypass the checksum protection. To do this, temporarily set the
configuration parameter .
Off-line Enabling of Checksums
The pg_checksums
application can be used to enable or disable data checksums, as well as
verify checksums, on an offline cluster.
Write-Ahead Logging (WAL)WALtransaction logWALWrite-Ahead Logging (WAL)
is a standard method for ensuring data integrity. A detailed
description can be found in most (if not all) books about
transaction processing. Briefly, WAL's central
concept is that changes to data files (where tables and indexes
reside) must be written only after those changes have been logged,
that is, after WAL records describing the changes have been flushed
to permanent storage. If we follow this procedure, we do not need
to flush data pages to disk on every transaction commit, because we
know that in the event of a crash we will be able to recover the
database using the log: any changes that have not been applied to
the data pages can be redone from the WAL records. (This is
roll-forward recovery, also known as REDO.)
Because WAL restores database file
contents after a crash, journaled file systems are not necessary for
reliable storage of the data files or WAL files. In fact, journaling
overhead can reduce performance, especially if journaling
causes file system data to be flushed
to disk. Fortunately, data flushing during journaling can
often be disabled with a file system mount option, e.g.,
data=writeback on a Linux ext3 file system.
Journaled file systems do improve boot speed after a crash.
Using WAL results in a
significantly reduced number of disk writes, because only the WAL
file needs to be flushed to disk to guarantee that a transaction is
committed, rather than every data file changed by the transaction.
The WAL file is written sequentially,
and so the cost of syncing the WAL is much less than the cost of
flushing the data pages. This is especially true for servers
handling many small transactions touching different parts of the data
store. Furthermore, when the server is processing many small concurrent
transactions, one fsync of the WAL file may
suffice to commit many transactions.
WAL also makes it possible to support on-line
backup and point-in-time recovery, as described in . By archiving the WAL data we can support
reverting to any time instant covered by the available WAL data:
we simply install a prior physical backup of the database, and
replay the WAL just as far as the desired time. What's more,
the physical backup doesn't have to be an instantaneous snapshot
of the database state — if it is made over some period of time,
then replaying the WAL for that period will fix any internal
inconsistencies.
Asynchronous Commitsynchronous commitasynchronous commitAsynchronous commit is an option that allows transactions
to complete more quickly, at the cost that the most recent transactions may
be lost if the database should crash. In many applications this is an
acceptable trade-off.
As described in the previous section, transaction commit is normally
synchronous: the server waits for the transaction's
WAL records to be flushed to permanent storage
before returning a success indication to the client. The client is
therefore guaranteed that a transaction reported to be committed will
be preserved, even in the event of a server crash immediately after.
However, for short transactions this delay is a major component of the
total transaction time. Selecting asynchronous commit mode means that
the server returns success as soon as the transaction is logically
completed, before the WAL records it generated have
actually made their way to disk. This can provide a significant boost
in throughput for small transactions.
Asynchronous commit introduces the risk of data loss. There is a short
time window between the report of transaction completion to the client
and the time that the transaction is truly committed (that is, it is
guaranteed not to be lost if the server crashes). Thus asynchronous
commit should not be used if the client will take external actions
relying on the assumption that the transaction will be remembered.
As an example, a bank would certainly not use asynchronous commit for
a transaction recording an ATM's dispensing of cash. But in many
scenarios, such as event logging, there is no need for a strong
guarantee of this kind.
The risk that is taken by using asynchronous commit is of data loss,
not data corruption. If the database should crash, it will recover
by replaying WAL up to the last record that was
flushed. The database will therefore be restored to a self-consistent
state, but any transactions that were not yet flushed to disk will
not be reflected in that state. The net effect is therefore loss of
the last few transactions. Because the transactions are replayed in
commit order, no inconsistency can be introduced — for example,
if transaction B made changes relying on the effects of a previous
transaction A, it is not possible for A's effects to be lost while B's
effects are preserved.
The user can select the commit mode of each transaction, so that
it is possible to have both synchronous and asynchronous commit
transactions running concurrently. This allows flexible trade-offs
between performance and certainty of transaction durability.
The commit mode is controlled by the user-settable parameter
, which can be changed in any of
the ways that a configuration parameter can be set. The mode used for
any one transaction depends on the value of
synchronous_commit when transaction commit begins.
Certain utility commands, for instance DROP TABLE, are
forced to commit synchronously regardless of the setting of
synchronous_commit. This is to ensure consistency
between the server's file system and the logical state of the database.
The commands supporting two-phase commit, such as PREPARE
TRANSACTION, are also always synchronous.
If the database crashes during the risk window between an
asynchronous commit and the writing of the transaction's
WAL records,
then changes made during that transaction will be lost.
The duration of the
risk window is limited because a background process (the WAL
writer) flushes unwritten WAL records to disk
every milliseconds.
The actual maximum duration of the risk window is three times
wal_writer_delay because the WAL writer is
designed to favor writing whole pages at a time during busy periods.
An immediate-mode shutdown is equivalent to a server crash, and will
therefore cause loss of any unflushed asynchronous commits.
Asynchronous commit provides behavior different from setting
= off.
fsync is a server-wide
setting that will alter the behavior of all transactions. It disables
all logic within PostgreSQL that attempts to synchronize
writes to different portions of the database, and therefore a system
crash (that is, a hardware or operating system crash, not a failure of
PostgreSQL itself) could result in arbitrarily bad
corruption of the database state. In many scenarios, asynchronous
commit provides most of the performance improvement that could be
obtained by turning off fsync, but without the risk
of data corruption.
also sounds very similar to
asynchronous commit, but it is actually a synchronous commit method
(in fact, commit_delay is ignored during an
asynchronous commit). commit_delay causes a delay
just before a transaction flushes WAL to disk, in
the hope that a single flush executed by one such transaction can also
serve other transactions committing at about the same time. The
setting can be thought of as a way of increasing the time window in
which transactions can join a group about to participate in a single
flush, to amortize the cost of the flush among multiple transactions.
WAL Configuration
There are several WAL-related configuration parameters that
affect database performance. This section explains their use.
Consult for general information about
setting server configuration parameters.
Checkpointscheckpoint
are points in the sequence of transactions at which it is guaranteed
that the heap and index data files have been updated with all
information written before that checkpoint. At checkpoint time, all
dirty data pages are flushed to disk and a special checkpoint record is
written to the WAL file. (The change records were previously flushed
to the WAL files.)
In the event of a crash, the crash recovery procedure looks at the latest
checkpoint record to determine the point in the WAL (known as the redo
record) from which it should start the REDO operation. Any changes made to
data files before that point are guaranteed to be already on disk.
Hence, after a checkpoint, WAL segments preceding the one containing
the redo record are no longer needed and can be recycled or removed. (When
WAL archiving is being done, the WAL segments must be
archived before being recycled or removed.)
The checkpoint requirement of flushing all dirty data pages to disk
can cause a significant I/O load. For this reason, checkpoint
activity is throttled so that I/O begins at checkpoint start and completes
before the next checkpoint is due to start; this minimizes performance
degradation during checkpoints.
The server's checkpointer process automatically performs
a checkpoint every so often. A checkpoint is begun every seconds, or if
is about to be exceeded,
whichever comes first.
The default settings are 5 minutes and 1 GB, respectively.
If no WAL has been written since the previous checkpoint, new checkpoints
will be skipped even if checkpoint_timeout has passed.
(If WAL archiving is being used and you want to put a lower limit on how
often files are archived in order to bound potential data loss, you should
adjust the parameter rather than the
checkpoint parameters.)
It is also possible to force a checkpoint by using the SQL
command CHECKPOINT.
Reducing checkpoint_timeout and/or
max_wal_size causes checkpoints to occur
more often. This allows faster after-crash recovery, since less work
will need to be redone. However, one must balance this against the
increased cost of flushing dirty data pages more often. If
is set (as is the default), there is
another factor to consider. To ensure data page consistency,
the first modification of a data page after each checkpoint results in
logging the entire page content. In that case,
a smaller checkpoint interval increases the volume of output to the WAL,
partially negating the goal of using a smaller interval,
and in any case causing more disk I/O.
Checkpoints are fairly expensive, first because they require writing
out all currently dirty buffers, and second because they result in
extra subsequent WAL traffic as discussed above. It is therefore
wise to set the checkpointing parameters high enough so that checkpoints
don't happen too often. As a simple sanity check on your checkpointing
parameters, you can set the
parameter. If checkpoints happen closer together than
checkpoint_warning seconds,
a message will be output to the server log recommending increasing
max_wal_size. Occasional appearance of such
a message is not cause for alarm, but if it appears often then the
checkpoint control parameters should be increased. Bulk operations such
as large COPY transfers might cause a number of such warnings
to appear if you have not set max_wal_size high
enough.
To avoid flooding the I/O system with a burst of page writes,
writing dirty buffers during a checkpoint is spread over a period of time.
That period is controlled by
, which is
given as a fraction of the checkpoint interval (configured by using
checkpoint_timeout).
The I/O rate is adjusted so that the checkpoint finishes when the
given fraction of
checkpoint_timeout seconds have elapsed, or before
max_wal_size is exceeded, whichever is sooner.
With the default value of 0.9,
PostgreSQL can be expected to complete each checkpoint
a bit before the next scheduled checkpoint (at around 90% of the last checkpoint's
duration). This spreads out the I/O as much as possible so that the checkpoint
I/O load is consistent throughout the checkpoint interval. The disadvantage of
this is that prolonging checkpoints affects recovery time, because more WAL
segments will need to be kept around for possible use in recovery. A user
concerned about the amount of time required to recover might wish to reduce
checkpoint_timeout so that checkpoints occur more frequently
but still spread the I/O across the checkpoint interval. Alternatively,
checkpoint_completion_target could be reduced, but this would
result in times of more intense I/O (during the checkpoint) and times of less I/O
(after the checkpoint completed but before the next scheduled checkpoint) and
therefore is not recommended.
Although checkpoint_completion_target could be set as high as
1.0, it is typically recommended to set it to no higher than 0.9 (the default)
since checkpoints include some other activities besides writing dirty buffers.
A setting of 1.0 is quite likely to result in checkpoints not being
completed on time, which would result in performance loss due to
unexpected variation in the number of WAL segments needed.
On Linux and POSIX platforms
allows to force the OS that pages written by the checkpoint should be
flushed to disk after a configurable number of bytes. Otherwise, these
pages may be kept in the OS's page cache, inducing a stall when
fsync is issued at the end of a checkpoint. This setting will
often help to reduce transaction latency, but it also can have an adverse
effect on performance; particularly for workloads that are bigger than
, but smaller than the OS's page cache.
The number of WAL segment files in pg_wal directory depends on
min_wal_size, max_wal_size and
the amount of WAL generated in previous checkpoint cycles. When old WAL
segment files are no longer needed, they are removed or recycled (that is,
renamed to become future segments in the numbered sequence). If, due to a
short-term peak of WAL output rate, max_wal_size is
exceeded, the unneeded segment files will be removed until the system
gets back under this limit. Below that limit, the system recycles enough
WAL files to cover the estimated need until the next checkpoint, and
removes the rest. The estimate is based on a moving average of the number
of WAL files used in previous checkpoint cycles. The moving average
is increased immediately if the actual usage exceeds the estimate, so it
accommodates peak usage rather than average usage to some extent.
min_wal_size puts a minimum on the amount of WAL files
recycled for future usage; that much WAL is always recycled for future use,
even if the system is idle and the WAL usage estimate suggests that little
WAL is needed.
Independently of max_wal_size,
the most recent megabytes of
WAL files plus one additional WAL file are
kept at all times. Also, if WAL archiving is used, old segments cannot be
removed or recycled until they are archived. If WAL archiving cannot keep up
with the pace that WAL is generated, or if archive_command
or archive_library
fails repeatedly, old WAL files will accumulate in pg_wal
until the situation is resolved. A slow or failed standby server that
uses a replication slot will have the same effect (see
).
In archive recovery or standby mode, the server periodically performs
restartpoints,restartpoint
which are similar to checkpoints in normal operation: the server forces
all its state to disk, updates the pg_control file to
indicate that the already-processed WAL data need not be scanned again,
and then recycles any old WAL segment files in the pg_wal
directory.
Restartpoints can't be performed more frequently than checkpoints on the
primary because restartpoints can only be performed at checkpoint records.
A restartpoint is triggered when a checkpoint record is reached if at
least checkpoint_timeout seconds have passed since the last
restartpoint, or if WAL size is about to exceed
max_wal_size. However, because of limitations on when a
restartpoint can be performed, max_wal_size is often exceeded
during recovery, by up to one checkpoint cycle's worth of WAL.
(max_wal_size is never a hard limit anyway, so you should
always leave plenty of headroom to avoid running out of disk space.)
There are two commonly used internal WAL functions:
XLogInsertRecord and XLogFlush.
XLogInsertRecord is used to place a new record into
the WAL buffers in shared memory. If there is no
space for the new record, XLogInsertRecord will have
to write (move to kernel cache) a few filled WAL
buffers. This is undesirable because XLogInsertRecord
is used on every database low level modification (for example, row
insertion) at a time when an exclusive lock is held on affected
data pages, so the operation needs to be as fast as possible. What
is worse, writing WAL buffers might also force the
creation of a new WAL segment, which takes even more
time. Normally, WAL buffers should be written
and flushed by an XLogFlush request, which is
made, for the most part, at transaction commit time to ensure that
transaction records are flushed to permanent storage. On systems
with high WAL output, XLogFlush requests might
not occur often enough to prevent XLogInsertRecord
from having to do writes. On such systems
one should increase the number of WAL buffers by
modifying the parameter. When
is set and the system is very busy,
setting wal_buffers higher will help smooth response times
during the period immediately following each checkpoint.
The parameter defines for how many
microseconds a group commit leader process will sleep after acquiring a
lock within XLogFlush, while group commit
followers queue up behind the leader. This delay allows other server
processes to add their commit records to the WAL buffers so that all of
them will be flushed by the leader's eventual sync operation. No sleep
will occur if is not enabled, or if fewer
than other sessions are currently
in active transactions; this avoids sleeping when it's unlikely that
any other session will commit soon. Note that on some platforms, the
resolution of a sleep request is ten milliseconds, so that any nonzero
commit_delay setting between 1 and 10000
microseconds would have the same effect. Note also that on some
platforms, sleep operations may take slightly longer than requested by
the parameter.
Since the purpose of commit_delay is to allow the
cost of each flush operation to be amortized across concurrently
committing transactions (potentially at the expense of transaction
latency), it is necessary to quantify that cost before the setting can
be chosen intelligently. The higher that cost is, the more effective
commit_delay is expected to be in increasing
transaction throughput, up to a point. The program can be used to measure the average time
in microseconds that a single WAL flush operation takes. A value of
half of the average time the program reports it takes to flush after a
single 8kB write operation is often the most effective setting for
commit_delay, so this value is recommended as the
starting point to use when optimizing for a particular workload. While
tuning commit_delay is particularly useful when the
WAL is stored on high-latency rotating disks, benefits can be
significant even on storage media with very fast sync times, such as
solid-state drives or RAID arrays with a battery-backed write cache;
but this should definitely be tested against a representative workload.
Higher values of commit_siblings should be used in
such cases, whereas smaller commit_siblings values
are often helpful on higher latency media. Note that it is quite
possible that a setting of commit_delay that is too
high can increase transaction latency by so much that total transaction
throughput suffers.
When commit_delay is set to zero (the default), it
is still possible for a form of group commit to occur, but each group
will consist only of sessions that reach the point where they need to
flush their commit records during the window in which the previous
flush operation (if any) is occurring. At higher client counts a
gangway effect tends to occur, so that the effects of group
commit become significant even when commit_delay is
zero, and thus explicitly setting commit_delay tends
to help less. Setting commit_delay can only help
when (1) there are some concurrently committing transactions, and (2)
throughput is limited to some degree by commit rate; but with high
rotational latency this setting can be effective in increasing
transaction throughput with as few as two clients (that is, a single
committing client with one sibling transaction).
The parameter determines how
PostgreSQL will ask the kernel to force
WAL updates out to disk.
All the options should be the same in terms of reliability, with
the exception of fsync_writethrough, which can sometimes
force a flush of the disk cache even when other options do not do so.
However, it's quite platform-specific which one will be the fastest.
You can test the speeds of different options using the program.
Note that this parameter is irrelevant if fsync
has been turned off.
Enabling the configuration parameter
(provided that PostgreSQL has been
compiled with support for it) will result in each
XLogInsertRecord and XLogFlush
WAL call being logged to the server log. This
option might be replaced by a more general mechanism in the future.
There are two internal functions to write WAL data to disk:
XLogWrite and issue_xlog_fsync.
When is enabled, the total
amounts of time XLogWrite writes and
issue_xlog_fsync syncs WAL data to disk are counted as
wal_write_time and wal_sync_time in
, respectively.
XLogWrite is normally called by
XLogInsertRecord (when there is no space for the new
record in WAL buffers), XLogFlush and the WAL writer,
to write WAL buffers to disk and call issue_xlog_fsync.
issue_xlog_fsync is normally called by
XLogWrite to sync WAL files to disk.
If wal_sync_method is either
open_datasync or open_sync,
a write operation in XLogWrite guarantees to sync written
WAL data to disk and issue_xlog_fsync does nothing.
If wal_sync_method is either fdatasync,
fsync, or fsync_writethrough,
the write operation moves WAL buffers to kernel cache and
issue_xlog_fsync syncs them to disk. Regardless
of the setting of track_wal_io_timing, the number
of times XLogWrite writes and
issue_xlog_fsync syncs WAL data to disk are also
counted as wal_write and wal_sync
in pg_stat_wal, respectively.
The parameter can be used to reduce
I/O wait times during recovery by instructing the kernel to initiate reads
of disk blocks that will soon be needed but are not currently in
PostgreSQL's buffer pool.
The and
settings limit prefetching
concurrency and distance, respectively. By default, it is set to
try, which enables the feature on systems where
posix_fadvise is available.
WAL InternalsLSN
WAL is automatically enabled; no action is
required from the administrator except ensuring that the
disk-space requirements for the WAL files are met,
and that any necessary tuning is done (see ).
WAL records are appended to the WAL
files as each new record is written. The insert position is described by
a Log Sequence Number (LSN) that is a byte offset into
the WAL, increasing monotonically with each new record.
LSN values are returned as the datatype
pg_lsn. Values can be
compared to calculate the volume of WAL data that
separates them, so they are used to measure the progress of replication
and recovery.
WAL files are stored in the directory
pg_wal under the data directory, as a set of
segment files, normally each 16 MB in size (but the size can be changed
by altering the initdb option). Each segment is
divided into pages, normally 8 kB each (this size can be changed via the
configure option). The WAL record headers
are described in access/xlogrecord.h; the record
content is dependent on the type of event that is being logged. Segment
files are given ever-increasing numbers as names, starting at
000000010000000000000001. The numbers do not wrap,
but it will take a very, very long time to exhaust the
available stock of numbers.
It is advantageous if the WAL is located on a different disk from the
main database files. This can be achieved by moving the
pg_wal directory to another location (while the server
is shut down, of course) and creating a symbolic link from the
original location in the main data directory to the new location.
The aim of WAL is to ensure that the log is
written before database records are altered, but this can be subverted by
disk drivesdisk drive that falsely report a
successful write to the kernel,
when in fact they have only cached the data and not yet stored it
on the disk. A power failure in such a situation might lead to
irrecoverable data corruption. Administrators should try to ensure
that disks holding PostgreSQL's
WAL files do not make such false reports.
(See .)
After a checkpoint has been made and the WAL flushed, the
checkpoint's position is saved in the file
pg_control. Therefore, at the start of recovery,
the server first reads pg_control and
then the checkpoint record; then it performs the REDO operation by
scanning forward from the WAL location indicated in the checkpoint
record. Because the entire content of data pages is saved in the
WAL on the first page modification after a checkpoint (assuming
is not disabled), all pages
changed since the checkpoint will be restored to a consistent
state.
To deal with the case where pg_control is
corrupt, we should support the possibility of scanning existing WAL
segments in reverse order — newest to oldest — in order to find the
latest checkpoint. This has not been implemented yet.
pg_control is small enough (less than one disk page)
that it is not subject to partial-write problems, and as of this writing
there have been no reports of database failures due solely to the inability
to read pg_control itself. So while it is
theoretically a weak spot, pg_control does not
seem to be a problem in practice.