It is important to back up your databases in case problems occur so that you can recover your data and be up and running again. MySQL offers a variety of backup strategies from which you can choose to select whatever methods best suit the requirements for your installation.
Briefly summarized, backup concepts with which you should be familiar include the following:
Logical versus physical backups
Online versus offline backups
Local versus remote backups
Snapshot backups
Full versus incremental backups
Point-in-time recovery
Backup scheduling, compression, and encryption
Table maintenance
More generally, the following discussion amplifies on the properties of different backup methods.
Logical versus physical (raw) backups. Logical backups save information represented as logical database structure (CREATE DATABASE, CREATE TABLE statements) and content (INSERT statements or delimited-text files). Physical backups consist of raw copies of the directories and files that store database contents.
Logical backup methods have these characteristics:
The backup is done by going through the MySQL server to obtain database structure and content information.
Backup is slower than physical methods because the server must access database information, convert it to logical format, and send it to the backup program.
Output is larger than for physical backup, paticularly when saved in text format.
Backup and restore granularity is available at the server level (all databases), database level (all tables in a particular database), or table level. This is true regardless of storage engine.
The backup does not include log or configuration files, or other database-related files that are not part of databases.
Backups stored in logical format are machine independent and highly portable.
Logical backups are performed with the MySQL server running (the server is not taken offline).
Logical backup tools include the mysqldump program and the SELECT ... INTO OUTFILE statement. These work for any storage engine, even MEMORY.
For restore, SQL-format dump files can be processed using the mysql client. To load delimited-text files, use the LOAD DATA INFILE statement or the mysqlimport client.
Physical backup methods have these characteristics:
The backup consists of exact copies of database directories and files. Typically this is a copy of all or part of the MySQL data directory. Data from MEMORY tables cannot be backed up this way because their contents are not stored on disk.
Physical backup methods are faster than logical because they involve only file copying without conversion.
Output is more compact than for logical backup.
Backup and restore granularity extends from the level of the entire data directory down to the level of individual files. This may or may not provide for table-level granularity, depending on storage engine. (Each MyISAM table corresponds uniquely to a set of files, but an InnoDB table shares file storage with other InnoDB tables.)
In addition to databases, the backup can include any related files such as log or configuration files.
Backups are portable only to other machines that have identical or similar hardware characteristics.
Backups can be performed while the MySQL server is not running. If the server is running, it is necessary to perform appropriate locking so that the server does not change database contents during the backup.
Physical backup tools include filesystem-level commands (such as cp, scp, tar, rsync), mysqlhotcopy for MyISAM tables, ibbackup for InnoDB tables, or START BACKUP for NDB tables.
For restore, files copied at the filesystem level or with mysqlhotcopy can be copied back to their original locations with filesystem commands; ibback restores InnoDB tables, and ndb_restore restores NDB tables.
Online versus offline backups. Online backups take place while the MySQL server is running so that the database information can be obtained from the server. Offline backups take place while the server is stopped. (This distinction can also be described as “hot” versus “cold” backups; a “warm” backup is one where the server remains running but locked against modifying data while you access database files externally.)
Online backup methods have these characteristics:
Less intrusive to other clients, which can connect to the MySQL server during the backup and may be able to access data depending on what operations they need to perform.
Care must be taken to impose appropriate locking so that data modifications do not take place that compromise backup integrity.
Offline backup methods have these characteristics:
Affects clients adversely because the server is unavailable during backup.
Simpler backup procedure because there is no possibility of interference from client activity.
Local versus remote backups. A local backup is performed on the same host where the MySQL server runs, whereas a remote backup is initiated from a different host.
mysqldump can connect to local or remote servers. For SQL output (CREATE and INSERT statements), local or remote dumps can be done and generate output on the client. For delimited-text output (with the --tab option), data files are created on the server host.
mysqlhotcopy performs only local backups: It connects to the server to lock it against data modifications and then copies local table files.
SELECT ... INTO OUTFILE can be initiated from a remote client host, but the output file is created on the server host.
Physical backup methods typically are initiated locally on the MySQL server host so that the server can be taken offline, although the destination for file copies might be remote.
Snapshot backups. Some filesystem implementations enable “snapshots” to be taken. These provide logical copies of the filesystem at a given point in time, without having to physically copy the entire filesystem. (For example, the implementation may use copy-on-write techniques so that only parts of the filesystem modified after the snapshot time need be copied.) MySQL itself does not provide the capability for taking filesystem snapshots. It is available through third-party solutions such as Veritas or LVM.
Full versus incremental backups. A full backup includes all data managed by a MySQL server at a given point in time. An incremental backup consists of the changes made to the data since the full backup. MySQL has different ways to perform full backups, such as those described in previous items. Incremental backups are made possible by enabling the server's binary log, which the server uses to record data changes.
Point-in-time recovery. One use for the binary log is to achieve point-in-time recovery. This is done by recovering first from the backup files to restore the server to its state when the backup was made, and then by re-executing changes in subsequently written binary log files to redo data modifications up to the desired point in time.
Backup scheduling, compression, and encryption. Backup scheduling is valuable for automating backup procedures. Compression of backup output reduces space requirements, and encryption of the output provides better security against unauthorized access of backed-up data. MySQL itself does not provide these capabilities. ibbackup can compress InnoDB backups, and compression or encryption of backup output can be achieved using filesystem utilities. Other third-party solutions may be available.
Table maintenance. Data integrity can be compromised if tables become corrupt. MySQL provides programs for checking tables and repairing them should problems be found. These programs apply primarily to MyISAM tables. See Section 6.5, “Table Maintenance and Crash Recovery”.
Additional resources
Resources related to backup or to maintaining data availability include the following:
Replication enables you to maintain identical data on multiple servers. This has several benefits, such as allowing client load to be distributed over servers, availability of data even if a given server is taken offline or fails, and the ability to make backups using a slave server without affecting the master. See Chapter 19, Replication.
MySQL Cluster provides a high-availability, high-redundancy version of MySQL adapted for the distributed computing environment. See MySQL Cluster. For information specifically about MySQL Cluster backup, see Online Backup of MySQL Cluster.
Distributed Replicated Block Device (DRBD) is another high-availability solution. It works by replicating a block device from a primary server to a secondary server at the block level. See Chapter 14, High Availability and Scalability
6.1. Database Backups
This section summarizes some general methods for making backups.
Making Backups by Copying Files
MyISAM tables are stored as files, so it is easy to do a backup by copying files. To get a consistent backup, do a LOCK TABLES on the relevant tables, followed by FLUSH TABLES for the tables. See Section 12.4.5, “LOCK TABLES and UNLOCK TABLES Syntax”, and Section 12.5.7.2, “FLUSH Syntax”. You need only a read lock; this allows other clients to continue to query the tables while you are making a copy of the files in the database directory. The FLUSH TABLES statement is needed to ensure that the all active index pages are written to disk before you start the backup.
Making Delimited-Text File Backups
To create a text file containing a table's data, you can use SELECT * INTO OUTFILE 'file_name' FROM tbl_name. The file is created on the MySQL server host, not the client host. For this statement, the output file cannot already exist because allowing files to be overwritten would constitute a security risk. See Section 12.2.8, “SELECT Syntax”. This method works for any kind of data file, but saves only table data, not the table structure.
To reload the output file, use LOAD DATA INFILE or mysqlimport.
You can also create a binary backup simply by copying all table files (*.frm, *.MYD, and *.MYI files), as long as the server isn't updating anything. The mysqlhotcopy script uses this method. (But note that these methods do not work if your database contains InnoDB tables. InnoDB does not necessarily store table contents in database directories, and mysqlhotcopy works only for MyISAM and ISAM tables.)
Using the Binary Log to Enable Incremental Backups
MySQL supports incremental backups: You must start the server with the --log-bin option to enable binary logging; see Section 5.2.4, “The Binary Log”. The binary log files provide you with the information you need to replicate changes to the database that are made subsequent to the point at which you performed a backup. At the moment you want to make an incremental backup (containing all changes that happened since the last full or incremental backup), you should rotate the binary log by using FLUSH LOGS. This done, you need to copy to the backup location all binary logs which range from the one of the moment of the last full or incremental backup to the last but one. These binary logs are the incremental backup; at restore time, you apply them as explained in Section 6.4, “Point-in-Time Recovery”. The next time you do a full backup, you should also rotate the binary log using FLUSH LOGS, mysqldump --flush-logs, or mysqlhotcopy --flushlog. See Section 4.5.4, “mysqldump — A Database Backup Program”, and Section 4.6.8, “mysqlhotcopy — A Database Backup Program”.
Backing Up Replication Slaves
If your MySQL server is a slave replication server, then regardless of the backup method you choose, you should also back up the master.info and relay-log.info files when you back up your slave's data. These files are always needed to resume replication after you restore the slave's data. If your slave is subject to replicating LOAD DATA INFILE commands, you should also back up any SQL_LOAD-* files that may exist in the directory specified by the --slave-load-tmpdir option. (This location defaults to the value of the tmpdir system variable if not specified.) The slave needs these files to resume replication of any interrupted LOAD DATA INFILE operations.
MySQL Enterprise The MySQL Enterprise Monitor provides numerous advisors that issue immediate warnings should replication issues arise. For more information, see http://www.mysql.com/products/enterprise/advisors.html.
If you have performance problems with your master server while making backups, one strategy that can help is to set up replication and perform backups on the slave rather than on the master. See Chapter 19, Replication.
Recovering Corrupt Tables
If you have to restore MyISAM tables that have become corrupt, try to recover them using REPAIR TABLE or myisamchk -r first. That should work in 99.9% of all cases. If myisamchk fails, try the following procedure. It is assumed that you have enabled binary logging by starting MySQL with the --log-bin option.
Restore the original mysqldump backup, or binary backup.
Execute the following command to re-run the updates in the binary logs:
shell> mysqlbinlog binlog.[0-9]* | mysql
In some cases, you may want to re-run only certain binary logs, from certain positions (usually you want to re-run all binary logs from the date of the restored backup, excepting possibly some incorrect statements). See Section 6.4, “Point-in-Time Recovery”.
Making Backups Using a Filesystem Snapshot
If you are using a Veritas filesystem, you can make a backup like this:
From a client program, execute FLUSH TABLES WITH READ LOCK.
This section discusses a procedure for performing backups that allows you to recover data after several types of crashes:
Operating system crash
Power failure
Filesystem crash
Hardware problem (hard drive, motherboard, and so forth)
The example commands do not include options such as --user and --password for the mysqldump and mysql programs. You should include such options as necessary so that the MySQL server allows you to connect to it.
We assume that data is stored in the InnoDB storage engine, which has support for transactions and automatic crash recovery. We also assume that the MySQL server is under load at the time of the crash. If it were not, no recovery would ever be needed.
For cases of operating system crashes or power failures, we can assume that MySQL's disk data is available after a restart. The InnoDB data files might not contain consistent data due to the crash, but InnoDB reads its logs and finds in them the list of pending committed and non-committed transactions that have not been flushed to the data files. InnoDB automatically rolls back those transactions that were not committed, and flushes to its data files those that were committed. Information about this recovery process is conveyed to the user through the MySQL error log. The following is an example log excerpt:
InnoDB: Database was not shut down normally.
InnoDB: Starting recovery from log files...
InnoDB: Starting log scan based on checkpoint at
InnoDB: log sequence number 0 13674004
InnoDB: Doing recovery: scanned up to log sequence number 0 13739520
InnoDB: Doing recovery: scanned up to log sequence number 0 13805056
InnoDB: Doing recovery: scanned up to log sequence number 0 13870592
InnoDB: Doing recovery: scanned up to log sequence number 0 13936128
...
InnoDB: Doing recovery: scanned up to log sequence number 0 20555264
InnoDB: Doing recovery: scanned up to log sequence number 0 20620800
InnoDB: Doing recovery: scanned up to log sequence number 0 20664692
InnoDB: 1 uncommitted transaction(s) which must be rolled back
InnoDB: Starting rollback of uncommitted transactions
InnoDB: Rolling back trx no 16745
InnoDB: Rolling back of trx no 16745 completed
InnoDB: Rollback of uncommitted transactions completed
InnoDB: Starting an apply batch of log records to the database...
InnoDB: Apply batch completed
InnoDB: Started
mysqld: ready for connections
For the cases of filesystem crashes or hardware problems, we can assume that the MySQL disk data is not available after a restart. This means that MySQL fails to start successfully because some blocks of disk data are no longer readable. In this case, it is necessary to reformat the disk, install a new one, or otherwise correct the underlying problem. Then it is necessary to recover our MySQL data from backups, which means that we must already have made backups. To make sure that is the case, we should design a backup policy.
6.2.1. Backup Policy
We all know that backups must be scheduled periodically. A full backup (a snapshot of the data at a point in time) can be done in MySQL with several tools. For example, InnoDB Hot Backup provides online non-blocking physical backup of the InnoDB data files, and mysqldump provides online logical backup. This discussion uses mysqldump.
Assume that we make a backup on Sunday at 1 p.m., when load is low. The following command makes a full backup of all our InnoDB tables in all databases:
This is an online, non-blocking backup that does not disturb the reads and writes on the tables. We assumed earlier that our tables are InnoDB tables, so --single-transaction uses a consistent read and guarantees that data seen by mysqldump does not change. (Changes made by other clients to InnoDB tables are not seen by the mysqldump process.) If we do also have other types of tables, we must assume that they are not changed during the backup. For example, for the MyISAM tables in the mysql database, we must assume that no administrative changes are being made to MySQL accounts during the backup.
The resulting .sql file produced by mysqldump contains a set of SQL INSERT statements that can be used to reload the dumped tables at a later time.
Full backups are necessary, but they are not always convenient. They produce large backup files and take time to generate. They are not optimal in the sense that each successive full backup includes all data, even that part that has not changed since the previous full backup. After we have made the initial full backup, it is more efficient to make incremental backups. They are smaller and take less time to produce. The tradeoff is that, at recovery time, you cannot restore your data just by reloading the full backup. You must also process the incremental backups to recover the incremental changes.
To make incremental backups, we need to save the incremental changes. The MySQL server should always be started with the --log-bin option so that it stores these changes in a file while it updates data. This option enables binary logging, so that the server writes each SQL statement that updates data into a file called a MySQL binary log. Looking at the data directory of a MySQL server that was started with the --log-bin option and that has been running for some days, we find these MySQL binary log files:
-rw-rw---- 1 guilhem guilhem 1277324 Nov 10 23:59 gbichot2-bin.000001
-rw-rw---- 1 guilhem guilhem 4 Nov 10 23:59 gbichot2-bin.000002
-rw-rw---- 1 guilhem guilhem 79 Nov 11 11:06 gbichot2-bin.000003
-rw-rw---- 1 guilhem guilhem 508 Nov 11 11:08 gbichot2-bin.000004
-rw-rw---- 1 guilhem guilhem 220047446 Nov 12 16:47 gbichot2-bin.000005
-rw-rw---- 1 guilhem guilhem 998412 Nov 14 10:08 gbichot2-bin.000006
-rw-rw---- 1 guilhem guilhem 361 Nov 14 10:07 gbichot2-bin.index
Each time it restarts, the MySQL server creates a new binary log file using the next number in the sequence. While the server is running, you can also tell it to close the current binary log file and begin a new one manually by issuing a FLUSH LOGS SQL statement or with a mysqladmin flush-logs command. mysqldump also has an option to flush the logs. The .index file in the data directory contains the list of all MySQL binary logs in the directory. This file is used for replication.
The MySQL binary logs are important for recovery because they form the set of incremental backups. If you make sure to flush the logs when you make your full backup, then any binary log files created afterward contain all the data changes made since the backup. Let's modify the previous mysqldump command a bit so that it flushes the MySQL binary logs at the moment of the full backup, and so that the dump file contains the name of the new current binary log:
After executing this command, the data directory contains a new binary log file, gbichot2-bin.000007. The resulting .sql file includes these lines:
-- Position to start replication or point-in-time recovery from
-- CHANGE MASTER TO MASTER_LOG_FILE='gbichot2-bin.000007',MASTER_LOG_POS=4;
Because the mysqldump command made a full backup, those lines mean two things:
The .sql file contains all changes made before any changes written to the gbichot2-bin.000007 binary log file or newer.
All data changes logged after the backup are not present in the .sql, but are present in the gbichot2-bin.000007 binary log file or newer.
On Monday at 1 p.m., we can create an incremental backup by flushing the logs to begin a new binary log file. For example, executing a mysqladmin flush-logs command creates gbichot2-bin.000008. All changes between the Sunday 1 p.m. full backup and Monday 1 p.m. will be in the gbichot2-bin.000007 file. This incremental backup is important, so it is a good idea to copy it to a safe place. (For example, back it up on tape or DVD, or copy it to another machine.) On Tuesday at 1 p.m., execute another mysqladmin flush-logs command. All changes between Monday 1 p.m. and Tuesday 1 p.m. will be in the gbichot2-bin.000008 file (which also should be copied somewhere safe).
The MySQL binary logs take up disk space. To free up space, purge them from time to time. One way to do this is by deleting the binary logs that are no longer needed, such as when we make a full backup:
Deleting the MySQL binary logs with mysqldump --delete-master-logs can be dangerous if your server is a replication master server, because slave servers might not yet fully have processed the contents of the binary log. The description for the PURGE MASTER LOGS statement explains what should be verified before deleting the MySQL binary logs. See Section 12.6.1.1, “PURGE MASTER LOGS Syntax”.
6.2.2. Using Backups for Recovery
Now, suppose that we have a catastrophic crash on Wednesday at 8 a.m. that requires recovery from backups. To recover, first we restore the last full backup we have (the one from Sunday 1 p.m.). The full backup file is just a set of SQL statements, so restoring it is very easy:
shell> mysql < backup_sunday_1_PM.sql
At this point, the data is restored to its state as of Sunday 1 p.m.. To restore the changes made since then, we must use the incremental backups; that is, the gbichot2-bin.000007 and gbichot2-bin.000008 binary log files. Fetch the files if necessary from where they were backed up, and then process their contents like this:
shell> mysqlbinlog gbichot2-bin.000007 gbichot2-bin.000008 | mysql
We now have recovered the data to its state as of Tuesday 1 p.m., but still are missing the changes from that date to the date of the crash. To not lose them, we would have needed to have the MySQL server store its MySQL binary logs into a safe location (RAID disks, SAN, ...) different from the place where it stores its data files, so that these logs were not on the destroyed disk. (That is, we can start the server with a --log-bin option that specifies a location on a different physical device from the one on which the data directory resides. That way, the logs are safe even if the device containing the directory is lost.) If we had done this, we would have the gbichot2-bin.000009 file at hand, and we could apply it using mysqlbinlog and mysql to restore the most recent data changes with no loss up to the moment of the crash.
6.2.3. Backup Strategy Summary
In case of an operating system crash or power failure, InnoDB itself does all the job of recovering data. But to make sure that you can sleep well, observe the following guidelines:
Always run the MySQL server with the --log-bin option, or even --log-bin=log_name, where the log file name is located on some safe media different from the drive on which the data directory is located. If you have such safe media, this technique can also be good for disk load balancing (which results in a performance improvement).
Make periodic full backups, using the mysqldump command shown earlier in Section 6.2.1, “Backup Policy”, that makes an online, non-blocking backup.
Make periodic incremental backups by flushing the logs with FLUSH LOGS or mysqladmin flush-logs.
The BACKUP DATABASE and RESTORE statements are available as of MySQL 6.0.5. They provide a way to make a copy of a database or set of databases at a given point in time, and a way to restore each database to its state as of that time. Restoring a backup can be combined with use of the binary log to accomplish point-in-time recovery: If the restore operation is done because data loss has occurred after the backup was made, restored databases can be brought up to the time of data loss by executing the data changes in the binary log between the times when the backup was made and when the data loss occurred.
A goal of the BACKUP DATABASE and RESTORE statements is to enable other database operations to proceed concurrently, to make it unnecessary to take databases offline or prevent clients from accessing them. BACKUP DATABASE must block some operations from occurring (such as dropping tables from a database while it is being backed up), but the attempt is made to keep blocking to a minimum. Generally, blocked operations are those involving Data Definition Language (DDL) statements. RESTORE must do more blocking because it writes database contents rather than just reading them.
The following discussion covers these aspects of BACKUP DATABASE and RESTORE:
Quick guide to making backups and restoring them
How BACKUP DATABASE and RESTORE work
Status reporting and monitoring for backup and restore operations
For additional information about the BACKUP DATABASE and RESTORE statements, see these sections of the manual:
Use the BACKUP DATABASE and RESTORE statements like this:
BACKUP DATABASE backs up one or more databases to a named file:
BACKUP DATABASE world TO '/tmp/mybackupfile';
To back up more than one database, separate the names by commas:
BACKUP DATABASE world, sakila TO '/tmp/mybackupfile';
To select all databases for backup, use the * selector as a shortcut:
BACKUP DATABASE * TO '/tmp/mybackupfile';
RESTORE restores databases using the contents of the backup file:
RESTORE FROM '/tmp/mybackupfile';
BACKUP DATABASE backs up database and table definitions, table data, stored routines, triggers, events, and views. TEMPORARY tables are not included. Tablespace backup support is limited to the Falcon storage engine. For anything else not explicitly listed, assume that it is not backed up. This includes but is not limited to items such as privileges, UDF definitions and files, logs, and option files.
BACKUP DATABASE currently does not back up the contents of the mysql database. This database contains the grant tables that define user accounts and their privileges, as well as other system information. To make a full server instance backup that includes account information in addition to data, use the BACKUP DATABASE statement together with the mysqldump program. In the following instructions, path represents the full pathname to the directory where you store your backup files.
Use mysqldump to back up the mysql database. This is a blocking operation that prevents changes to the database during the dump, but the mysql database normally is relatively small and can be dumped quickly:
shell> mysqldump --databases mysql > path/mysql-db.sql
Use BACKUP DATABASE to back up the data from other databases. This is a non-blocking operation:
mysql> BACKUP DATABASE * TO 'path/other-dbs.bak';
Restore the server instance later like this:
To restore the user accounts, reload the mysql database dump file using the mysql client:
shell> mysql -u root -p < path/mysql-db.sql
To restore the data for other databases, use RESTORE with the image file produced by BACKUP DATABASE:
A backup operation creates a backup of one or more databases at a given point in time and saves it as a backup image, a file that contains the backup data (table contents) and metadata (definitions for databases, tables, and other objects, and server information).
The backup is intended to provide a consistent snapshot of the backed-up data as of the point at which the operation began, and it is intended to provide online operation as much as possible that allows other server activity to proceed without blocking.
A backup operation begins at time t1 and ends at time t2, producing a backup image that contains the backup state (database state) at time t, where t1 < t < t2. The time t is called the validity point of the backup image. It represents the time when all storage engines are synchronized for the backup. Restoring this image restores the state to be the same as it was at time t.
Consistency of the backup means that these constraints must be true:
Data from transactional tables is included only for committed transactions.
Data from non-transactional tables is included only for completed statements.
Referential integrity is maintained between all backed-up tables within a given backup image.
The referential-integrity constraint does not necessarily hold if two tables are related but only one of them is included in a backup. Restoring the backup then would restore only the backed-up table, which can produce tables for which referential integrity no longer holds.
For a backup to proceed properly, certain types of server activity must be blocked, so the backup system incorporates a commit blocker and a DDL blocker.
The commit blocker has these properties:
Changes for non-transactional tables must be blocked.
Changes for transactional tables are not blocked, but only changes that have been committed when the backup occurs appear in the backup. Changes that occur during the backup operation are not included in the backup image.
When a backup or restore operation is in progress, it is not allowable to modify the structure of databases or tables. Consequently, the DDL blocker prevents these statements from executing during the operation:
ALTER DATABASE
ALTER TABLE
CREATE DATABASE
CREATE INDEX
CREATE TABLE
DROP DATABASE
DROP INDEX
DROP TABLE
OPTIMIZE TABLE
RENAME TABLE
REPAIR TABLE
TRUNCATE TABLE
Currently, all instances of the the DDL statements in the list are blocked, even for database or table objects that are not included in the backup. Eventually, the goal is to block only DDL statements for objects in the backup.
Blocking works in both directions. A backup or restore blocks DDL statements, but if a backup or restore operation is initiated while DDL statements are in progress, the operation waits until the statements have finished.
Implementation of BACKUP DATABASE and RESTORE uses an architecture with the following design:
The MySQL server communicates with the backup kernel.
The backup kernel is responsible for communicating with backup engines and for handling metadata (definitions for databases, tables, and other objects, as well as server information).
Each backup engine provides backup and restore drivers for the backup kernel to use.
An engine's backup and restore drivers perform actual transfer of data (table contents).
The backup system chooses from among the backup engines available to it:
There is a default backup engine to be used if a better one is not found. This engine provides default backup and restore drivers that use a blocking algorithm. For example, the backup driver locks all tables at the start of the backup and unlocks them after the last one is processed (which may occur before the operation is complete).
A consistent-snapshot engine implements the same kind of backup as that made by mysqldump --single-transaction.
The backup driver for the snapshot engine works with only those storage engines that support consistent read via the handler interface, which currently includes only InnoDB and Falcon. The backup driver creates a logical backup because it reads rows one at a time and returns them to the backup kernel to be stored in the backup image.
A backup image must have contents that are consistent with the binary log coordinates taken from the time of the backup. Otherwise, point-in-time recovery using the backup image plus the binary log contents will not work correctly. BACKUP DATABASE synchronizes with binary logging to make sure that the backup image and binary log are consistent with each other. This way, if data loss occurs later, use of the backup image combined with the binary log makes makes point-in-time recovery possible:
Restore the backup image
Re-execute binary log contents beginning from the coordinates of the backup's validity point up to the desired point of recovery
6.3.3. BACKUP DATABASE and RESTORE Status Reporting and Monitoring
MySQL provides information about the status or progress of BACKUP DATABASE or RESTORE operations in the following ways:
SHOW PROCESSLIST displays information while a thread performing a backup or restore is executing.
Upon successful completion, the BACKUP DATABASE and RESTORE statements return a result set with the backup number. (This number is the ID for the corresponding row or rows in the metadata tables described later.) Warnings produced during the operation can be displayed with SHOW WARNINGS.
If errors occur during a backup or restore operation, they are written to the error log, recorded in the progress tables, and are available via the SHOW ERRORS and SHOW WARNINGS statements.
If a fatal error occurs, the BACKUP DATABASE or RESTORE statement reports it to the user.
The server maintains online_backup and online_backup_progress tables in the mysql database that contain metadata. (If you upgrade to MySQL 6.0.5 or later from an older version, be sure to run mysql_upgrade to ensure that these tables exist.)
The online_backup table contains a row for each backup and restore operation. A row is created when an operation begins and is updated as the operation progresses. The rows in this table serve as a history of all backup and restore operations performed on the server. The table can be queried to obtained detailed information about the operations or as a means to create a summary of the operations. The rows are not removed from the table by the server. Any table maintenance, such as removing old rows, is intended to be performed by the database administrator.
The online_backup_progress table contains progress data describing the steps in the most recent backup or restore operation. There may be multiple rows for the operation. Rows are added to this table over the course of the operation and are not updated. This enables the table to be used to track the current progress of the operation. Each row in the table represents a step in the operation and may contain informational statements, errors, and other pertinent information. The data in this table has a limited lifetime. At the start of each operation, the table is truncated and new data is added. The database administrator should not need to perform maintenance for this data.
Currently, there are no INFORMATION_SCHEMA tables corresponding to the online_backup and online_backup_progress tables.
The online_backup table has this structure:
CREATE TABLE online_backup (
backup_id BIGINT UNSIGNED PRIMARY KEY AUTO_INCREMENT,
process_id INT UNSIGNED NOT NULL,
binlog_pos INT UNSIGNED DEFAULT 0,
binlog_file CHAR(64),
backup_state ENUM('complete', 'starting', 'validity point',
'running', 'error', 'cancel') NOT NULL,
operation ENUM('backup', 'restore') NOT NULL,
error_num INT NOT NULL DEFAULT 0,
num_objects INT UNSIGNED NOT NULL DEFAULT 0,
total_bytes BIGINT UNSIGNED,
validity_point_time DATETIME,
start_time DATETIME,
stop_time DATETIME,
host_or_server_name CHAR (30),
username CHAR (30),
backup_file CHAR (100),
user_comment VARCHAR (200) DEFAULT NULL,
command VARCHAR (512),
engines VARCHAR (100),
) ENGINE=MYISAM;
The online_backup columns are used as follows:
backup_id
The ID for the table row. BACKUP DATABASE and RESTORE return a result set containing a backup ID, which is the value that tells you which row in the online_backup table corresponds to the backup or restore operation.
process_id
The process ID that the operation ran as.
binlog_pos, binlog_file
For a backup, the binary log position and filename at the time the validity point is generated (the time when all storage engines are synchronized). Before that time, the values are 0 and NULL.
backup_state
The status of the operation.
operation
The type of operation.
error_num
The error from this operation (0 = no error).
num_objects
The number of objects in the backup.
total_bytes
The size of the backup image file in bytes.
validity_point_time
For a backup, this is the time that the validity point was generated. Before that time, the value is NULL. For a restore, the value currently is always NULL.
start_time, stop_time
The date and time when the operation started and stopped.
host_or_server_name
The server name where the operation ran.
username
The name of the user who ran the operation.
backup_file
The name of the backup image file.
user_comment
The comment from the user entered at the command line.
command
The statement used to perform the operation.
engines
The names of the storage engines used in the operation.
The online_backup_progress table has this structure:
CREATE TABLE online_backup_progress (
backup_id BIGINT UNSIGNED NOT NULL
object CHAR (30) NOT NULL
start_time DATATIME
stop_time DATATIME
total_bytes BIGINT
progress BIGINT UNSIGNED
error_num INT NOT NULL DEFAULT 0
notes CHAR(100)
) ENGINE=MYISAM;
The online_backup_progress columns are used as follows:
backup_id
The backup_id value of the online_backup table row with which the rows in the online_backup_progress table are associated.
object
The object being operated on.
start_time, stop_time
The date and time when the operation started and stopped.
If a MySQL server was started with the --log-bin option to enable binary logging, you can use the mysqlbinlog utility to recover data from the binary log files, starting from a specified point in time (for example, since your last backup) until the present or another specified point in time. For information on enabling the binary log and using mysqlbinlog, see Section 5.2.4, “The Binary Log”, and Section 4.6.7, “mysqlbinlog — Utility for Processing Binary Log Files”.
To restore data from a binary log, you must know the location and name of the current binary log file. By default, the server creates binary log files in the data directory, but a pathname can be specified with the --log-bin option to place the files in a different location. Typically the option is given in an option file (that is, my.cnf or my.ini, depending on your system). It can also be given on the command line when the server is started. To determine the name of the current binary log file, issue the following statement:
mysql> SHOW MASTER STATUS
If you prefer, you can execute the following command from the command line instead:
shell> mysql -u root -p -E -e "SHOW MASTER STATUS"
Enter the root password for your server when mysql prompts you for it.
To indicate the start and end times for recovery, specify the --start-date and --stop-date options for mysqlbinlog, in DATETIME format. As an example, suppose that exactly at 10:00 a.m. on April 20, 2005 an SQL statement was executed that deleted a large table. To restore the table and data, you could restore the previous night's backup, and then execute the following command:
shell> mysqlbinlog --stop-date="2005-04-20 9:59:59" \/var/log/mysql/bin.123456 | mysql -u root -p
This command recovers all of the data up until the date and time given by the --stop-date option. If you did not detect the erroneous SQL statement that was entered until hours later, you will probably also want to recover the activity that occurred afterward. Based on this, you could run mysqlbinlog again with a start date and time, like so:
shell> mysqlbinlog --start-date="2005-04-20 10:01:00" \/var/log/mysql/bin.123456 | mysql -u root -p
In this command, the SQL statements logged from 10:01 a.m. on will be re-executed. The combination of restoring of the previous night's dump file and the two mysqlbinlog commands restores everything up until one second before 10:00 a.m. and everything from 10:01 a.m. on. You should examine the log to be sure of the exact times to specify for the commands. To display the log file contents without executing them, use this command:
Then open the file with a text editor to examine it.
6.4.2. Specifying Positions for Recovery
Instead of specifying dates and times, the --start-position and --stop-position options for mysqlbinlog can be used for specifying log positions. They work the same as the start and stop date options, except that you specify log position numbers rather than dates. Using positions may enable you to be more precise about which part of the log to recover, especially if many transactions occurred around the same time as a damaging SQL statement. To determine the position numbers, run mysqlbinlog for a range of times near the time when the unwanted transaction was executed, but redirect the results to a text file for examination. This can be done like so:
This command creates a small text file in the /tmp directory that contains the SQL statements around the time that the deleterious SQL statement was executed. Open this file with a text editor and look for the statement that you don't want to repeat. Determine the positions in the binary log for stopping and resuming the recovery and make note of them. Positions are labeled as log_pos followed by a number. After restoring the previous backup file, use the position numbers to process the binary log file. For example, you would use commands something like these:
shell> mysqlbinlog --stop-position="368312" /var/log/mysql/bin.123456 \| mysql -u root -p
shell> mysqlbinlog --start-position="368315" /var/log/mysql/bin.123456 \| mysql -u root -p
The first command recovers all the transactions up until the stop position given. The second command recovers all transactions from the starting position given until the end of the binary log. Because the output of mysqlbinlog includes SET TIMESTAMP statements before each SQL statement recorded, the recovered data and related MySQL logs will reflect the original times at which the transactions were executed.
This section discusses how to use myisamchk to check or repair MyISAM tables (tables that have .MYD and .MYI files for storing data and indexes). For general myisamchk background, see Section 4.6.3, “myisamchk — MyISAM Table-Maintenance Utility”.
You can use myisamchk to get information about your database tables or to check, repair, or optimize them. The following sections describe how to perform these operations and how to set up a table maintenance schedule.
Even though table repair with myisamchk is quite secure, it is always a good idea to make a backup before doing a repair or any maintenance operation that could make a lot of changes to a table.
myisamchk operations that affect indexes can cause FULLTEXT indexes to be rebuilt with full-text parameters that are incompatible with the values used by the MySQL server. To avoid this problem, follow the guidelines in Section 4.6.3.1, “myisamchk General Options”.
In many cases, you may find it simpler to do MyISAM table maintenance using the SQL statements that perform operations that myisamchk can do:
To check or repair MyISAM tables, use CHECK TABLE or REPAIR TABLE.
This section describes how to check for and deal with data corruption in MySQL databases. If your tables become corrupted frequently, you should try to find the reason why. See Section B.1.4.2, “What to Do If MySQL Keeps Crashing”.
If you run mysqld with external locking disabled (which is the default as of MySQL 4.0), you cannot reliably use myisamchk to check a table when mysqld is using the same table. If you can be certain that no one will access the tables through mysqld while you run myisamchk, you only have to execute mysqladmin flush-tables before you start checking the tables. If you cannot guarantee this, you must stop mysqld while you check the tables. If you run myisamchk to check tables that mysqld is updating at the same time, you may get a warning that a table is corrupt even when it is not.
If the server is run with external locking enabled, you can use myisamchk to check tables at any time. In this case, if the server tries to update a table that myisamchk is using, the server will wait for myisamchk to finish before it continues.
If you use myisamchk to repair or optimize tables, you must always ensure that the mysqld server is not using the table (this also applies if external locking is disabled). If you don't stop mysqld, you should at least do a mysqladmin flush-tables before you run myisamchk. Your tables may become corrupted if the server and myisamchk access the tables simultaneously.
When performing crash recovery, it is important to understand that each MyISAM table tbl_name in a database corresponds to three files in the database directory:
File
Purpose
tbl_name.frm
Definition (format) file
tbl_name.MYD
Data file
tbl_name.MYI
Index file
Each of these three file types is subject to corruption in various ways, but problems occur most often in data files and index files.
myisamchk works by creating a copy of the .MYD data file row by row. It ends the repair stage by removing the old .MYD file and renaming the new file to the original file name. If you use --quick, myisamchk does not create a temporary .MYD file, but instead assumes that the .MYD file is correct and generates only a new index file without touching the .MYD file. This is safe, because myisamchk automatically detects whether the .MYD file is corrupt and aborts the repair if it is. You can also specify the --quick option twice to myisamchk. In this case, myisamchk does not abort on some errors (such as duplicate-key errors) but instead tries to resolve them by modifying the .MYD file. Normally the use of two --quick options is useful only if you have too little free disk space to perform a normal repair. In this case, you should at least make a backup of the table before running myisamchk.
6.5.2. How to Check MyISAM Tables for Errors
To check a MyISAM table, use the following commands:
myisamchk tbl_name
This finds 99.99% of all errors. What it cannot find is corruption that involves only the data file (which is very unusual). If you want to check a table, you should normally run myisamchk without options or with the -s (silent) option.
myisamchk -m tbl_name
This finds 99.999% of all errors. It first checks all index entries for errors and then reads through all rows. It calculates a checksum for all key values in the rows and verifies that the checksum matches the checksum for the keys in the index tree.
myisamchk -e tbl_name
This does a complete and thorough check of all data (-e means “extended check”). It does a check-read of every key for each row to verify that they indeed point to the correct row. This may take a long time for a large table that has many indexes. Normally, myisamchk stops after the first error it finds. If you want to obtain more information, you can add the -v (verbose) option. This causes myisamchk to keep going, up through a maximum of 20 errors.
myisamchk -e -i tbl_name
This is like the previous command, but the -i option tells myisamchk to print additional statistical information.
In most cases, a simple myisamchk command with no arguments other than the table name is sufficient to check a table.
6.5.3. How to Repair Tables
The discussion in this section describes how to use myisamchk on MyISAM tables (extensions .MYI and .MYD).
Symptoms of corrupted tables include queries that abort unexpectedly and observable errors such as these:
tbl_name.frm is locked against change
Can't find file tbl_name.MYI (Errcode: nnn)
Unexpected end of file
Record file is crashed
Got error nnn from table handler
To get more information about the error, run perrornnn, where nnn is the error number. The following example shows how to use perror to find the meanings for the most common error numbers that indicate a problem with a table:
shell> perror 126 127 132 134 135 136 141 144 145
MySQL error code 126 = Index file is crashed
MySQL error code 127 = Record-file is crashed
MySQL error code 132 = Old database file
MySQL error code 134 = Record was already deleted (or record file crashed)
MySQL error code 135 = No more room in record file
MySQL error code 136 = No more room in index file
MySQL error code 141 = Duplicate unique key or constraint on write or update
MySQL error code 144 = Table is crashed and last repair failed
MySQL error code 145 = Table was marked as crashed and should be repaired
Note that error 135 (no more room in record file) and error 136 (no more room in index file) are not errors that can be fixed by a simple repair. In this case, you must use ALTER TABLE to increase the MAX_ROWS and AVG_ROW_LENGTH table option values:
ALTER TABLE tbl_name MAX_ROWS=xxx AVG_ROW_LENGTH=yyy;
If you do not know the current table option values, use SHOW CREATE TABLE.
For the other errors, you must repair your tables. myisamchk can usually detect and fix most problems that occur.
The repair process involves up to four stages, described here. Before you begin, you should change location to the database directory and check the permissions of the table files. On Unix, make sure that they are readable by the user that mysqld runs as (and to you, because you need to access the files you are checking). If it turns out you need to modify files, they must also be writable by you.
If you are going to repair a table from the command line, you must first stop the mysqld server. Note that when you do mysqladmin shutdown on a remote server, the mysqld server is still alive for a while after mysqladmin returns, until all statement-processing has stopped and all index changes have been flushed to disk.
Stage 1: Checking your tables
Run myisamchk *.MYI or myisamchk -e *.MYI if you have more time. Use the -s (silent) option to suppress unnecessary information.
If the mysqld server is stopped, you should use the --update-state option to tell myisamchk to mark the table as “checked.”
You have to repair only those tables for which myisamchk announces an error. For such tables, proceed to Stage 2.
If you get unexpected errors when checking (such as out of memory errors), or if myisamchk crashes, go to Stage 3.
Stage 2: Easy safe repair
First, try myisamchk -r -q tbl_name (-r -q means “quick recovery mode”). This attempts to repair the index file without touching the data file. If the data file contains everything that it should and the delete links point at the correct locations within the data file, this should work, and the table is fixed. Start repairing the next table. Otherwise, use the following procedure:
Make a backup of the data file before continuing.
Use myisamchk -r tbl_name (-r means “recovery mode”). This removes incorrect rows and deleted rows from the data file and reconstructs the index file.
If the preceding step fails, use myisamchk --safe-recover tbl_name. Safe recovery mode uses an old recovery method that handles a few cases that regular recovery mode does not (but is slower).
Note
If you want a repair operation to go much faster, you should set the values of the sort_buffer_size and key_buffer_size variables each to about 25% of your available memory when running myisamchk.
If you get unexpected errors when repairing (such as out of memory errors), or if myisamchk crashes, go to Stage 3.
Stage 3: Difficult repair
You should reach this stage only if the first 16KB block in the index file is destroyed or contains incorrect information, or if the index file is missing. In this case, it is necessary to create a new index file. Do so as follows:
Move the data file to a safe place.
Use the table description file to create new (empty) data and index files:
shell> mysql db_name
mysql> SET AUTOCOMMIT=1;
mysql> TRUNCATE TABLE tbl_name;
mysql> quit
Copy the old data file back onto the newly created data file. (Do not just move the old file back onto the new file. You want to retain a copy in case something goes wrong.)
Important
If you are using replication, you should stop it prior to performing the above procedure, since it involves filesystem operations, and these are not logged by MySQL.
Go back to Stage 2. myisamchk -r -q should work. (This should not be an endless loop.)
You can also use the REPAIR TABLE tbl_name USE_FRM SQL statement, which performs the whole procedure automatically. There is also no possibility of unwanted interaction between a utility and the server, because the server does all the work when you use REPAIR TABLE. See Section 12.5.2.5, “REPAIR TABLE Syntax”.
Stage 4: Very difficult repair
You should reach this stage only if the .frm description file has also crashed. That should never happen, because the description file is not changed after the table is created:
Restore the description file from a backup and go back to Stage 3. You can also restore the index file and go back to Stage 2. In the latter case, you should start with myisamchk -r.
If you do not have a backup but know exactly how the table was created, create a copy of the table in another database. Remove the new data file, and then move the .frm description and .MYI index files from the other database to your crashed database. This gives you new description and index files, but leaves the .MYD data file alone. Go back to Stage 2 and attempt to reconstruct the index file.
6.5.4. Table Optimization
To coalesce fragmented rows and eliminate wasted space that results from deleting or updating rows, run myisamchk in recovery mode:
shell> myisamchk -r tbl_name
You can optimize a table in the same way by using the OPTIMIZE TABLE SQL statement. OPTIMIZE TABLE does a table repair and a key analysis, and also sorts the index tree so that key lookups are faster. There is also no possibility of unwanted interaction between a utility and the server, because the server does all the work when you use OPTIMIZE TABLE. See Section 12.5.2.4, “OPTIMIZE TABLE Syntax”.
myisamchk has a number of other options that you can use to improve the performance of a table:
To obtain a description of a table or statistics about it, use the commands shown here. We explain some of the information in more detail later.
myisamchk -d tbl_name
Runs myisamchk in “describe mode” to produce a description of your table. If you start the MySQL server with external locking disabled, myisamchk may report an error for a table that is updated while it runs. However, because myisamchk does not change the table in describe mode, there is no risk of destroying data.
myisamchk -d -v tbl_name
Adding -v runs myisamchk in verbose mode so that it produces more information about what it is doing.
myisamchk -eis tbl_name
Shows only the most important information from a table. This operation is slow because it must read the entire table.
myisamchk -eiv tbl_name
This is like -eis, but tells you what is being done.
Sample output for some of these commands follows. They are based on a table with these data and index file sizes:
-rw-rw-r-- 1 monty tcx 317235748 Jan 12 17:30 company.MYD
-rw-rw-r-- 1 davida tcx 96482304 Jan 12 18:35 company.MYI
Example of myisamchk -d output:
MyISAM file: company.MYI
Record format: Fixed length
Data records: 1403698 Deleted blocks: 0
Recordlength: 226
table description:
Key Start Len Index Type
1 2 8 unique double
2 15 10 multip. text packed stripped
3 219 8 multip. double
4 63 10 multip. text packed stripped
5 167 2 multip. unsigned short
6 177 4 multip. unsigned long
7 155 4 multip. text
8 138 4 multip. unsigned long
9 177 4 multip. unsigned long
193 1 text
Example of myisamchk -d -v output:
MyISAM file: company
Record format: Fixed length
File-version: 1
Creation time: 1999-10-30 12:12:51
Recover time: 1999-10-31 19:13:01
Status: checked
Data records: 1403698 Deleted blocks: 0
Datafile parts: 1403698 Deleted data: 0
Datafile pointer (bytes): 3 Keyfile pointer (bytes): 3
Max datafile length: 3791650815 Max keyfile length: 4294967294
Recordlength: 226
table description:
Key Start Len Index Type Rec/key Root Blocksize
1 2 8 unique double 1 15845376 1024
2 15 10 multip. text packed stripped 2 25062400 1024
3 219 8 multip. double 73 40907776 1024
4 63 10 multip. text packed stripped 5 48097280 1024
5 167 2 multip. unsigned short 4840 55200768 1024
6 177 4 multip. unsigned long 1346 65145856 1024
7 155 4 multip. text 4995 75090944 1024
8 138 4 multip. unsigned long 87 85036032 1024
9 177 4 multip. unsigned long 178 96481280 1024
193 1 text
Example of myisamchk -eis output:
Checking MyISAM file: company
Key: 1: Keyblocks used: 97% Packed: 0% Max levels: 4
Key: 2: Keyblocks used: 98% Packed: 50% Max levels: 4
Key: 3: Keyblocks used: 97% Packed: 0% Max levels: 4
Key: 4: Keyblocks used: 99% Packed: 60% Max levels: 3
Key: 5: Keyblocks used: 99% Packed: 0% Max levels: 3
Key: 6: Keyblocks used: 99% Packed: 0% Max levels: 3
Key: 7: Keyblocks used: 99% Packed: 0% Max levels: 3
Key: 8: Keyblocks used: 99% Packed: 0% Max levels: 3
Key: 9: Keyblocks used: 98% Packed: 0% Max levels: 4
Total: Keyblocks used: 98% Packed: 17%
Records: 1403698 M.recordlength: 226
Packed: 0%
Recordspace used: 100% Empty space: 0%
Blocks/Record: 1.00
Record blocks: 1403698 Delete blocks: 0
Recorddata: 317235748 Deleted data: 0
Lost space: 0 Linkdata: 0
User time 1626.51, System time 232.36
Maximum resident set size 0, Integral resident set size 0
Non physical pagefaults 0, Physical pagefaults 627, Swaps 0
Blocks in 0 out 0, Messages in 0 out 0, Signals 0
Voluntary context switches 639, Involuntary context switches 28966
Example of myisamchk -eiv output:
Checking MyISAM file: company
Data records: 1403698 Deleted blocks: 0
- check file-size
- check delete-chain
block_size 1024:
index 1:
index 2:
index 3:
index 4:
index 5:
index 6:
index 7:
index 8:
index 9:
No recordlinks
- check index reference
- check data record references index: 1
Key: 1: Keyblocks used: 97% Packed: 0% Max levels: 4
- check data record references index: 2
Key: 2: Keyblocks used: 98% Packed: 50% Max levels: 4
- check data record references index: 3
Key: 3: Keyblocks used: 97% Packed: 0% Max levels: 4
- check data record references index: 4
Key: 4: Keyblocks used: 99% Packed: 60% Max levels: 3
- check data record references index: 5
Key: 5: Keyblocks used: 99% Packed: 0% Max levels: 3
- check data record references index: 6
Key: 6: Keyblocks used: 99% Packed: 0% Max levels: 3
- check data record references index: 7
Key: 7: Keyblocks used: 99% Packed: 0% Max levels: 3
- check data record references index: 8
Key: 8: Keyblocks used: 99% Packed: 0% Max levels: 3
- check data record references index: 9
Key: 9: Keyblocks used: 98% Packed: 0% Max levels: 4
Total: Keyblocks used: 9% Packed: 17%
- check records and index references
*** LOTS OF ROW NUMBERS DELETED ***
Records: 1403698 M.recordlength: 226 Packed: 0%
Recordspace used: 100% Empty space: 0% Blocks/Record: 1.00
Record blocks: 1403698 Delete blocks: 0
Recorddata: 317235748 Deleted data: 0
Lost space: 0 Linkdata: 0
User time 1639.63, System time 251.61
Maximum resident set size 0, Integral resident set size 0
Non physical pagefaults 0, Physical pagefaults 10580, Swaps 0
Blocks in 4 out 0, Messages in 0 out 0, Signals 0
Voluntary context switches 10604, Involuntary context switches 122798
Explanations for the types of information myisamchk produces are given here. “Keyfile” refers to the index file. “Record” and “row” are synonymous.
MyISAM file
Name of the MyISAM (index) file.
File-version
Version of MyISAM format. Currently always 2.
Creation time
When the data file was created.
Recover time
When the index/data file was last reconstructed.
Data records
How many rows are in the table.
Deleted blocks
How many deleted blocks still have reserved space. You can optimize your table to minimize this space. See Section 6.5.4, “Table Optimization”.
Datafile parts
For dynamic-row format, this indicates how many data blocks there are. For an optimized table without fragmented rows, this is the same as Data records.
Deleted data
How many bytes of unreclaimed deleted data there are. You can optimize your table to minimize this space. See Section 6.5.4, “Table Optimization”.
Datafile pointer
The size of the data file pointer, in bytes. It is usually 2, 3, 4, or 5 bytes. Most tables manage with 2 bytes, but this cannot be controlled from MySQL yet. For fixed tables, this is a row address. For dynamic tables, this is a byte address.
Keyfile pointer
The size of the index file pointer, in bytes. It is usually 1, 2, or 3 bytes. Most tables manage with 2 bytes, but this is calculated automatically by MySQL. It is always a block address.
Max datafile length
How long the table data file can become, in bytes.
Max keyfile length
How long the table index file can become, in bytes.
Recordlength
How much space each row takes, in bytes.
Record format
The format used to store table rows. The preceding examples use Fixed length. Other possible values are Compressed and Packed.
table description
A list of all keys in the table. For each key, myisamchk displays some low-level information:
Key
This key's number.
Start
Where in the row this portion of the index starts.
Len
How long this portion of the index is. For packed numbers, this should always be the full length of the column. For strings, it may be shorter than the full length of the indexed column, because you can index a prefix of a string column.
Index
Whether a key value can exist multiple times in the index. Possible values are unique or multip. (multiple).
Type
What data type this portion of the index has. This is a MyISAM data type with the possible values packed, stripped, or empty.
Root
Address of the root index block.
Blocksize
The size of each index block. By default this is 1024, but the value may be changed at compile time when MySQL is built from source.
Rec/key
This is a statistical value used by the optimizer. It tells how many rows there are per value for this index. A unique index always has a value of 1. This may be updated after a table is loaded (or greatly changed) with myisamchk -a. If this is not updated at all, a default value of 30 is given.
For the table shown in the examples, there are two table description lines for the ninth index. This indicates that it is a multiple-part index with two parts.
Keyblocks used
What percentage of the keyblocks are used. When a table has just been reorganized with myisamchk, as for the table in the examples, the values are very high (very near the theoretical maximum).
Packed
MySQL tries to pack key values that have a common suffix. This can only be used for indexes on CHAR and VARCHAR columns. For long indexed strings that have similar leftmost parts, this can significantly reduce the space used. In the third of the preceding examples, the fourth key is 10 characters long and a 60% reduction in space is achieved.
Max levels
How deep the B-tree for this key is. Large tables with long key values get high values.
Records
How many rows are in the table.
M.recordlength
The average row length. This is the exact row length for tables with fixed-length rows, because all rows have the same length.
Packed
MySQL strips spaces from the end of strings. The Packed value indicates the percentage of savings achieved by doing this.
Recordspace used
What percentage of the data file is used.
Empty space
What percentage of the data file is unused.
Blocks/Record
Average number of blocks per row (that is, how many links a fragmented row is composed of). This is always 1.0 for fixed-format tables. This value should stay as close to 1.0 as possible. If it gets too large, you can reorganize the table. See Section 6.5.4, “Table Optimization”.
Recordblocks
How many blocks (links) are used. For fixed-format tables, this is the same as the number of rows.
Deleteblocks
How many blocks (links) are deleted.
Recorddata
How many bytes in the data file are used.
Deleted data
How many bytes in the data file are deleted (unused).
Lost space
If a row is updated to a shorter length, some space is lost. This is the sum of all such losses, in bytes.
Linkdata
When the dynamic table format is used, row fragments are linked with pointers (4 to 7 bytes each). Linkdata is the sum of the amount of storage used by all such pointers.
Another way to check tables is to use myisamchk. For maintenance purposes, you can use myisamchk -s. The -s option (short for --silent) causes myisamchk to run in silent mode, printing messages only when errors occur.
It is also a good idea to enable automatic MyISAM table checking. For example, whenever the machine has done a restart in the middle of an update, you usually need to check each table that could have been affected before it is used further. (These are “expected crashed tables.”) To check MyISAM tables automatically, start the server with the --myisam-recover option. See Section 5.1.2, “Command Options”.
You should also check your tables regularly during normal system operation. At MySQL AB, we run a cron job to check all our important tables once a week, using a line like this in a crontab file:
This prints out information about crashed tables so that we can examine and repair them when needed.
Because we have not had any unexpectedly crashed tables (tables that become corrupted for reasons other than hardware trouble) for several years, once a week is more than sufficient for us.
We recommend that to start with, you execute myisamchk -s each night on all tables that have been updated during the last 24 hours, until you come to trust MySQL as much as we do.
Normally, MySQL tables need little maintenance. If you are performing many updates to MyISAM tables with dynamic-sized rows (tables with VARCHAR, BLOB, or TEXT columns) or have tables with many deleted rows you may want to defragment/reclaim space from the tables from time to time. You can do this by using OPTIMIZE TABLE on the tables in question. Alternatively, if you can stop the mysqld server for a while, change location into the data directory and use this command while the server is stopped: