a26cdf9a61
FossilOrigin-Name: 3e66ea6f61abc0f95af3bb46ebc0e10b4dcd069b
571 lines
24 KiB
Tcl
571 lines
24 KiB
Tcl
#
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# Run this script to generated a lockingv3.html output file
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#
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set rcsid {$Id: }
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source common.tcl
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header {File Locking And Concurrency In SQLite Version 3}
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proc HEADING {level title {label {}}} {
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global pnum
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incr pnum($level)
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foreach i [array names pnum] {
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if {$i>$level} {set pnum($i) 0}
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}
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set h [expr {$level+1}]
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if {$h>6} {set h 6}
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set n $pnum(1).$pnum(2)
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for {set i 3} {$i<=$level} {incr i} {
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append n .$pnum($i)
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}
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if {$label!=""} {
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puts "<a name=\"$label\">"
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}
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puts "<h$h>$n $title</h$h>"
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}
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set pnum(1) 0
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set pnum(2) 0
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set pnum(3) 0
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set pnum(4) 0
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set pnum(5) 0
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set pnum(6) 0
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set pnum(7) 0
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set pnum(8) 0
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HEADING 1 {File Locking And Concurrency In SQLite Version 3}
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puts {
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<p>Version 3 of SQLite introduces a more complex locking and journaling
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mechanism designed to improve concurrency and reduce the writer starvation
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problem. The new mechanism also allows atomic commits of transactions
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involving multiple database files.
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This document describes the new locking mechanism.
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The intended audience is programmers who want to understand and/or modify
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the pager code and reviewers working to verify the design
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of SQLite version 3.
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</p>
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}
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HEADING 1 {Overview} overview
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puts {
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<p>
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Locking and concurrency control are handled by the the
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<a href="http://www.sqlite.org/cvstrac/getfile/sqlite/src/pager.c">
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pager module</a>.
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The pager module is responsible for making SQLite "ACID" (Atomic,
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Consistent, Isolated, and Durable). The pager module makes sure changes
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happen all at once, that either all changes occur or none of them do,
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that two or more processes do not try to access the database
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in incompatible ways at the same time, and that once changes have been
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written they persist until explicitly deleted. The pager also provides
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an memory cache of some of the contents of the disk file.</p>
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<p>The pager is unconcerned
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with the details of B-Trees, text encodings, indices, and so forth.
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From the point of view of the pager the database consists of
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a single file of uniform-sized blocks. Each block is called a
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"page" and is usually 1024 bytes in size. The pages are numbered
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beginning with 1. So the first 1024 bytes of the database are called
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"page 1" and the second 1024 bytes are call "page 2" and so forth. All
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other encoding details are handled by higher layers of the library.
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The pager communicates with the operating system using one of several
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modules
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(Examples:
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<a href="http://www.sqlite.org/cvstrac/getfile/sqlite/src/os_unix.c">
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os_unix.c</a>,
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<a href="http://www.sqlite.org/cvstrac/getfile/sqlite/src/os_win.c">
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os_win.c</a>)
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that provides a uniform abstraction for operating system services.
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</p>
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<p>The pager module effectively controls access for separate threads, or
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separate processes, or both. Throughout this document whenever the
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word "process" is written you may substitute the word "thread" without
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changing the truth of the statement.</p>
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}
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HEADING 1 {Locking} locking
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puts {
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<p>
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From the point of view of a single process, a database file
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can be in one of five locking states:
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</p>
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<p>
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<table cellpadding="20">
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<tr><td valign="top">UNLOCKED</td>
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<td valign="top">
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No locks are held on the database. The database may be neither read nor
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written. Any internally cached data is considered suspect and subject to
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verification against the database file before being used. Other
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processes can read or write the database as their own locking states
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permit. This is the default state.
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</td></tr>
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<tr><td valign="top">SHARED</td>
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<td valign="top">
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The database may be read but not written. Any number of
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processes can hold SHARED locks at the same time, hence there can be
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many simultaneous readers. But no other thread or process is allowed
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to write to the database file while one or more SHARED locks are active.
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</td></tr>
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<tr><td valign="top">RESERVED</td>
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<td valign="top">
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A RESERVED lock means that the process is planning on writing to the
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database file at some point in the future but that it is currently just
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reading from the file. Only a single RESERVED lock may be active at one
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time, though multiple SHARED locks can coexist with a single RESERVED lock.
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RESERVED differs from PENDING in that new SHARED locks can be acquired
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while there is a RESERVED lock.
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</td></tr>
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<tr><td valign="top">PENDING</td>
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<td valign="top">
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A PENDING lock means that the process holding the lock wants to write
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to the database as soon as possible and is just waiting on all current
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SHARED locks to clear so that it can get an EXCLUSIVE lock. No new
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SHARED locks are permitted against the database if
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a PENDING lock is active, though existing SHARED locks are allowed to
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continue.
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</td></tr>
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<tr><td valign="top">EXCLUSIVE</td>
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<td valign="top">
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An EXCLUSIVE lock is needed in order to write to the database file.
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Only one EXCLUSIVE lock is allowed on the file and no other locks of
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any kind are allowed to coexist with an EXCLUSIVE lock. In order to
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maximize concurrency, SQLite works to minimize the amount of time that
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EXCLUSIVE locks are held.
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</td></tr>
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</table>
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</p>
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<p>
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The operating system interface layer understands and tracks all five
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locking states described above.
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The pager module only tracks four of the five locking states.
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A PENDING lock is always just a temporary
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stepping stone on the path to an EXCLUSIVE lock and so the pager module
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does not track PENDING locks.
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</p>
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}
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HEADING 1 {The Rollback Journal} rollback
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puts {
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<p>Any time a process wants to make a changes to a database file, it
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first records enough information in the <em>rollback journal</em> to
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restore the database file back to its initial condition. Thus, before
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altering any page of the database, the original contents of that page
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must be written into the journal. The journal also records the initial
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size of the database so that if the database file grows it can be truncated
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back to its original size on a rollback.</p>
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<p>The rollback journal is a ordinary disk file that has the same name as
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the database file with the suffix "<tt>-journal</tt>" added.</p>
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<p>If SQLite is working with multiple databases at the same time
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(using the ATTACH command) then each database has its own journal.
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But there is also a separate aggregate journal
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called the <em>master journal</em>.
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The master journal does not contain page data used for rolling back
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changes. Instead the master journal contains the names of the
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individual file journals for each of the ATTACHed databases. Each of
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the individual file journals also contain the name of the master journal.
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If there are no ATTACHed databases (or if none of the ATTACHed database
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is participating in the current transaction) no master journal is
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created and the normal rollback journal contains an empty string
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in the place normally reserved for recording the name of the master
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journal.</p>
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<p>A individual file journal is said to be <em>hot</em>
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if it needs to be rolled back
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in order to restore the integrity of its database.
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A hot journal is created when a process is in the middle of a database
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update and a program or operating system crash or power failure prevents
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the update from completing.
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Hot journals are an exception condition.
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Hot journals exist to recover from crashes and power failures.
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If everything is working correctly
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(that is, if there are no crashes or power failures)
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you will never get a hot journal.
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</p>
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<p>
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If no master journal is involved, then
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a journal is hot if it exists and its corresponding database file
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does not have a RESERVED lock.
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If a master journal is named in the file journal, then the file journal
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is hot if its master journal exists and there is no RESERVED
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lock on the corresponding database file.
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It is important to understand when a journal is hot so the
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preceding rules will be repeated in bullets:
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</p>
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<ul>
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<li>A journal is hot if...
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<ul>
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<li>It exists, and</li>
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<li>It's master journal exists or the master journal name is an
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empty string, and</li>
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<li>There is no RESERVED lock on the corresponding database file.</li>
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</ul>
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</li>
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</ul>
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}
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HEADING 2 {Dealing with hot journals} hot_journals
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puts {
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<p>
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Before reading from a a database file, SQLite always checks to see if that
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database file has a hot journal. If the file does have a hot journal, then
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the journal is rolled back before the file is read. In this way, we ensure
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that the database file is in a consistent state before it is read.
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</p>
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<p>When a process wants to read from a database file, it followed
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the following sequence of steps:
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</p>
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<ol>
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<li>Open the database file and obtain a SHARED lock. If the SHARED lock
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cannot be obtained, fail immediately and return SQLITE_BUSY.</li>
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<li>Check to see if the database file has a hot journal. If the file
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does not have a hot journal, we are done. Return immediately.
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If there is a hot journal, that journal must be rolled back by
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the subsequent steps of this algorithm.</li>
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<li>Acquire a PENDING lock then an EXCLUSIVE lock on the database file.
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(Note: Do not acquire a RESERVED lock because that would make
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other processes think the journal was no longer hot.) If we
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fail to acquire these locks it means another process
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is already trying to do the rollback. In that case,
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drop all locks, close the database, and return SQLITE_BUSY. </li>
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<li>Read the journal file and roll back the changes.</li>
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<li>Wait for the rolled back changes to be written onto
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the surface of the disk. This protects the integrity of the database
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in case another power failure or crash occurs.</li>
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<li>Delete the journal file.</li>
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<li>Delete the master journal file if it is safe to do so.
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This step is optional. It is here only to prevent stale
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master journals from cluttering up the disk drive.
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See the discussion below for details.</li>
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<li>Drop the EXCLUSIVE and PENDING locks but retain the SHARED lock.</li>
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</ol>
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<p>After the algorithm above completes successfully, it is safe to
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read from the database file. Once all reading has completed, the
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SHARED lock is dropped.</p>
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}
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HEADING 2 {Deleting stale master journals} stale_master_journals
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puts {
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<p>A stale master journal is a master journal that is no longer being
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used for anything. There is no requirement that stale master journals
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be deleted. The only reason for doing so is to free up disk space.</p>
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<p>A master journal is stale if no individual file journals are pointing
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to it. To figure out if a master journal is stale, we first read the
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master journal to obtain the names of all of its file journals. Then
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we check each of those file journals. If any of the file journals named
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in the master journal exists and points back to the master journal, then
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the master journal is not stale. If all file journals are either missing
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or refer to other master journals or no master journal at all, then the
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master journal we are testing is stale and can be safely deleted.</p>
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}
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HEADING 1 {Writing to a database file} writing
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puts {
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<p>To write to a database, a process must first acquire a SHARED lock
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as described above (possibly rolling back incomplete changes if there
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is a hot journal).
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After a SHARED lock is obtained, a RESERVED lock must be acquired.
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The RESERVED lock signals that the process intends to write to the
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database at some point in the future. Only one process at a time
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can hold a RESERVED lock. But other processes can continue to read
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the database while the RESERVED lock is held.
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</p>
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<p>If the process that wants to write is unable to obtain a RESERVED
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lock, it must mean that another process already has a RESERVED lock.
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In that case, the write attempt fails and returns SQLITE_BUSY.</p>
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<p>After obtaining a RESERVED lock, the process that wants to write
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creates a rollback journal. The header of the journal is initialized
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with the original size of the database file. Space in the journal header
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is also reserved for a master journal name, though the master journal
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name is initially empty.</p>
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<p>Before making changes to any page of the database, the process writes
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the original content of that page into the rollback journal. Changes
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to pages are held in memory at first and are not written to the disk.
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The original database file remains unaltered, which means that other
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processes can continue to read the database.</p>
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<p>Eventually, the writing process will want to update the database
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file, either because its memory cache has filled up or because it is
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ready to commit its changes. Before this happens, the writer must
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make sure no other process is reading the database and that the rollback
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journal data is safely on the disk surface so that it can be used to
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rollback incomplete changes in the event of a power failure.
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The steps are as follows:</p>
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<ol>
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<li>Make sure all rollback journal data has actually been written to
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the surface of the disk (and is not just being held in the operating
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system's or disk controllers cache) so that if a power failure occurs
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the data will still be there after power is restored.</li>
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<li>Obtain a PENDING lock and then an EXCLUSIVE lock on the database file.
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If other processes are still have SHARED locks, the writer might have
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to wait until those SHARED locks clear before it is able to obtain
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an EXCLUSIVE lock.</li>
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<li>Write all page modifications currently held in memory out to the
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original database disk file.</li>
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</ol>
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<p>
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If the reason for writing to the database file is because the memory
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cache was full, then the writer will not commit right away. Instead,
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the writer might continue to make changes to other pages. Before
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subsequent changes are written to the database file, the rollback
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journal must be flushed to disk again. Note also that the EXCLUSIVE
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lock that the writer obtained in order to write to the database initially
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must be held until all changes are committed. That means that no other
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processes are able to access the database from the
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time the memory cache first spills to disk until the transaction
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commits.
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</p>
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<p>
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When a writer is ready to commit its changes, it executes the following
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steps:
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</p>
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<ol>
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<li value="4">
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Obtain an EXCLUSIVE lock on the database file and
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make sure all memory changes have been written to the database file
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using the algorithm of steps 1-3 above.</li>
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<li>Flush all database file changes to the disk. Wait for those changes
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to actually be written onto the disk surface.</li>
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<li>Delete the journal file. This is the instant when the changes are
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committed. Prior to deleting the journal file, if a power failure
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or crash occurs, the next process to open the database will see that
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it has a hot journal and will roll the changes back.
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After the journal is deleted, there will no longer be a hot journal
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and the changes will persist.
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</li>
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<li>Drop the EXCLUSIVE and PENDING locks from the database file.
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</li>
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</ol>
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<p>As soon as PENDING lock is released from the database file, other
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processes can begin reading the database again. In the current implementation,
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the RESERVED lock is also released, but that is not essential. Future
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versions of SQLite might provide a "CHECKPOINT" SQL command that will
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commit all changes made so far within a transaction but retain the
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RESERVED lock so that additional changes can be made without given
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any other process an opportunity to write.</p>
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<p>If a transaction involves multiple databases, then a more complex
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commit sequence is used, as follows:</p>
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<ol>
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<li value="4">
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Make sure all individual database files have an EXCLUSIVE lock and a
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valid journal.
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<li>Create a master-journal. The name of the master-journal is arbitrary.
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(The current implementation appends random suffixes to the name of the
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main database file until it finds a name that does not previously exist.)
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Fill the master journal with the names of all the individual journals
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and flush its contents to disk.
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<li>Write the name of the master journal into
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all individual journals (in space set aside for that purpose in the
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headers of the individual journals) and flush the contents of the
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individual journals to disk and wait for those changes to reach the
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disk surface.
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<li>Flush all database file changes to the disk. Wait for those changes
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to actually be written onto the disk surface.</li>
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<li>Delete the master journal file. This is the instant when the changes are
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committed. Prior to deleting the master journal file, if a power failure
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or crash occurs, the individual file journals will be considered hot
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and will be rolled back by the next process that
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attempts to read them. After the master journal has been deleted,
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the file journals will no longer be considered hot and the changes
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will persist.
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</li>
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<li>Delete all individual journal files.
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<li>Drop the EXCLUSIVE and PENDING locks from all database files.
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</li>
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</ol>
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}
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HEADING 2 {Writer starvation} writer_starvation
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puts {
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<p>In SQLite version 2, if many processes are reading from the database,
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it might be the case that there is never a time when there are
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no active readers. And if there is always at least one read lock on the
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database, no process would ever be able to make changes to the database
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because it would be impossible to acquire a write lock. This situation
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is called <em>writer starvation</em>.</p>
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<p>SQLite version 3 seeks to avoid writer starvation through the use of
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the PENDING lock. The PENDING lock allows existing readers to continue
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but prevents new readers from connecting to the database. So when a
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process wants to write a busy database, it can set a PENDING lock which
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will prevent new readers from coming in. Assuming existing readers do
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eventually complete, all SHARED locks will eventually clear and the
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writer will be given a chance to make its changes.</p>
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}
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HEADING 1 {How To Corrupt Your Database Files} how_to_corrupt
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puts {
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<p>The pager module is robust but it is not completely failsafe.
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It can be subverted. This section attempts to identify and explain
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the risks.</p>
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<p>
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Clearly, a hardware or operating system fault that introduces incorrect data
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into the middle of the database file or journal will cause problems.
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Likewise,
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if a rogue process opens a database file or journal and writes malformed
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data into the middle of it, then the database will become corrupt.
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There is not much that can be done about these kinds of problems
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so they are given no further attention.
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</p>
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<p>
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SQLite uses POSIX advisory locks to implement locking on Unix. On
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windows it uses the LockFile(), LockFileEx(), and UnlockFile() system
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calls. SQLite assumes that these system calls all work as advertised. If
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that is not the case, then database corruption can result. One should
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note that POSIX advisory locking is known to be buggy or even unimplemented
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on many NFS implementations (including recent versions of Mac OS X)
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and that there are reports of locking problems
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for network filesystems under windows. Your best defense is to not
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use SQLite for files on a network filesystem.
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</p>
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<p>
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SQLite uses the fsync() system call to flush data to the disk under Unix and
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it uses the FlushFileBuffers() to do the same under windows. Once again,
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SQLite assumes that these operating system services function as advertised.
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But it has been reported that fsync() and FlushFileBuffers() do not always
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work correctly, especially with inexpensive IDE disks. Apparently some
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manufactures of IDE disks have defective controller chips that report
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that data has reached the disk surface when in fact the data is still
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in volatile cache memory in the disk drive electronics. There are also
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reports that windows sometimes chooses to ignore FlushFileBuffers() for
|
|
unspecified reasons. The author cannot verify any of these reports.
|
|
But if they are true, it means that database corruption is a possibility
|
|
following an unexpected power loss. These are hardware and/or operating
|
|
system bugs that SQLite is unable to defend against.
|
|
</p>
|
|
|
|
<p>
|
|
If a crash or power failure occurs and results in a hot journal but that
|
|
journal is deleted, the next process to open the database will not
|
|
know that it contains changes that need to be rolled back. The rollback
|
|
will not occur and the database will be left in an inconsistent state.
|
|
Rollback journals might be deleted for any number of reasons:
|
|
</p>
|
|
|
|
<ul>
|
|
<li>An administrator might be cleaning up after an OS crash or power failure,
|
|
see the journal file, think it is junk, and delete it.</li>
|
|
<li>Someone (or some process) might rename the database file but fail to
|
|
also rename its associated journal.</li>
|
|
<li>If the database file has aliases (hard or soft links) and the file
|
|
is opened by a different alias than the one used to create the journal,
|
|
then the journal will not be found. To avoid this problem, you should
|
|
not create links to SQLite database files.</li>
|
|
<li>Filesystem corruption following a power failure might cause the
|
|
journal to be renamed or deleted.</li>
|
|
</ul>
|
|
|
|
<p>
|
|
The last (fourth) bullet above merits additional comment. When SQLite creates
|
|
a journal file on Unix, it opens the directory that contains that file and
|
|
calls fsync() on the directory, in an effort to push the directory information
|
|
to disk. But suppose some other process is adding or removing unrelated
|
|
files to the directory that contains the database and journal at the the
|
|
moment of a power failure. The supposedly unrelated actions of this other
|
|
process might result in the journal file being dropped from the directory and
|
|
moved into "lost+found". This is an unlikely scenario, but it could happen.
|
|
The best defenses are to use a journaling filesystem or to keep the
|
|
database and journal in a directory by themselves.
|
|
</p>
|
|
|
|
<p>
|
|
For a commit involving multiple databases and a master journal, if the
|
|
various databases were on different disk volumes and a power failure occurs
|
|
during the commit, then when the machine comes back up the disks might
|
|
be remounted with different names. Or some disks might not be mounted
|
|
at all. When this happens the individual file journals and the master
|
|
journal might not be able to find each other. The worst outcome from
|
|
this scenario is that the commit ceases to be atomic.
|
|
Some databases might be rolled back and others might not.
|
|
All databases will continue to be self-consistent.
|
|
To defend against this problem, keep all databases
|
|
on the same disk volume and/or remount disks using exactly the same names
|
|
after a power failure.
|
|
</p>
|
|
}
|
|
|
|
HEADING 1 {Transaction Control At The SQL Level} transaction_control
|
|
|
|
puts {
|
|
<p>
|
|
The changes to locking and concurrency control in SQLite version 3 also
|
|
introduce some subtle changes in the way transactions work at the SQL
|
|
language level.
|
|
By default, SQLite version 3 operates in <em>autocommit</em> mode.
|
|
In autocommit mode,
|
|
all changes to the database are committed as soon as all operations associated
|
|
with the current database connection complete.</p>
|
|
|
|
<p>The SQL command "BEGIN TRANSACTION" (the TRANSACTION keyword
|
|
is optional) is used to take SQLite out of autocommit mode.
|
|
Note that the BEGIN command does not acquire any locks on the database.
|
|
After a BEGIN command, a SHARED lock will be acquired when the first
|
|
SELECT statement is executed. A RESERVED lock will be acquired when
|
|
the first INSERT, UPDATE, or DELETE statement is executed. No EXCLUSIVE
|
|
lock is acquired until either the memory cache fills up and must
|
|
be spilled to disk or until the transaction commits. In this way,
|
|
the system delays blocking read access to the file file until the
|
|
last possible moment.
|
|
</p>
|
|
|
|
<p>The SQL command "COMMIT" does not actually commit the changes to
|
|
disk. It just turns autocommit back on. Then, at the conclusion of
|
|
the command, the regular autocommit logic takes over and causes the
|
|
actual commit to disk to occur.
|
|
The SQL command "ROLLBACK" also operates by turning autocommit back on,
|
|
but it also sets a flag that tells the autocommit logic to rollback rather
|
|
than commit.</p>
|
|
|
|
<p>If the SQL COMMIT command turns autocommit on and the autocommit logic
|
|
then tries to commit change but fails because some other process is holding
|
|
a SHARED lock, then autocommit is turned back off automatically. This
|
|
allows the user to retry the COMMIT at a later time after the SHARED lock
|
|
has had an opportunity to clear.</p>
|
|
|
|
<p>If multiple commands are being executed against the same SQLite database
|
|
connection at the same time, the autocommit is deferred until the very
|
|
last command completes. For example, if a SELECT statement is being
|
|
executed, the execution of the command will pause as each row of the
|
|
result is returned. During this pause other INSERT, UPDATE, or DELETE
|
|
commands can be executed against other tables in the database. But none
|
|
of these changes will commit until the original SELECT statement finishes.
|
|
</p>
|
|
}
|
|
|
|
|
|
footer $rcsid
|