WAL is automatically enabled; no action is required from the administrator except ensuring that the disk-space requirements for the WAL logs are met, and that any necessary tuning is done (see Section 30.4).
WAL records are appended to the WAL
logs as each new record is written. The insert position is described by
a Log Sequence Number (LSN) that is a byte offset into
the logs, 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 logs 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 --wal-segsize
initdb option). Each segment is
divided into pages, normally 8 kB each (this size can be changed via the
--with-wal-blocksize
configure option). The log 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 log 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 drives 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 log files do not make such false reports. (See Section 30.1.)
After a checkpoint has been made and the log 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 log location indicated in the checkpoint
record. Because the entire content of data pages is saved in the
log on the first page modification after a checkpoint (assuming
full_page_writes 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 log
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.