InnoDB
supports data-at-rest encryption for
file-per-table
tablespaces, general
tablespaces, the mysql
system tablespace, redo
logs, and undo logs.
You can set an encryption default for schemas and general tablespaces; this permits DBAs to control whether tables created in those schemas and tablespaces are encrypted.
InnoDB
data-at-rest encryption features and
capabilities are described under the following topics in this
section.
InnoDB
uses a two tier encryption key
architecture, consisting of a master encryption key and tablespace
keys. When a tablespace is encrypted, a tablespace key is
encrypted and stored in the tablespace header. When an application
or authenticated user wants to access encrypted tablespace data,
InnoDB
uses a master encryption key to decrypt
the tablespace key. The decrypted version of a tablespace key
never changes, but the master encryption key can be changed as
required. This action is referred to as master key
rotation.
The data-at-rest encryption feature relies on a keyring component or plugin for master encryption key management.
All MySQL editions provide a
component_keyring_file
component, which stores
keyring data in a file local to the server host.
MySQL Enterprise Edition offers additional keyring components and plugins:
component_keyring_encrypted_file
: Stores keyring data in an encrypted, password-protected file local to the server host.keyring_okv
: A KMIP 1.1 plugin for use with KMIP-compatible back end keyring storage products. Supported KMIP-compatible products include centralized key management solutions such as Oracle Key Vault, Gemalto KeySecure, Thales Vormetric key management server, and Fornetix Key Orchestration.keyring_aws
: Communicates with the Amazon Web Services Key Management Service (AWS KMS) as a back end for key generation and uses a local file for key storage.keyring_hashicorp
: Communicates with HashiCorp Vault for back end storage.
For encryption key management, the
component_keyring_file
and
component_keyring_encrypted_file
components
are not intended as a regulatory compliance solution. Security
standards such as PCI, FIPS, and others require use of key
management systems to secure, manage, and protect encryption
keys in key vaults or hardware security modules (HSMs).
A secure and robust encryption key management solution is critical for security and for compliance with various security standards. When the data-at-rest encryption feature uses a centralized key management solution, the feature is referred to as “MySQL Enterprise Transparent Data Encryption (TDE)”.
The data-at-rest encryption feature supports the Advanced Encryption Standard (AES) block-based encryption algorithm. It uses Electronic Codebook (ECB) block encryption mode for tablespace key encryption and Cipher Block Chaining (CBC) block encryption mode for data encryption.
For frequently asked questions about the data-at-rest encryption feature, see Section A.17, “MySQL 9.1 FAQ: InnoDB Data-at-Rest Encryption”.
A keyring component or plugin must be installed and configured at startup. Early loading ensures that the component or plugin is available prior to initialization of the
InnoDB
storage engine. For keyring installation and configuration instructions, see Section 8.4.4, “The MySQL Keyring”. The instructions show how to ensure that the chosen component or plugin is active.Only one keyring component or plugin should be enabled at a time. Enabling multiple keyring components or plugins is unsupported and results may not be as anticipated.
ImportantOnce encrypted tablespaces are created in a MySQL instance, the keyring component or plugin that was loaded when creating the encrypted tablespace must continue to be loaded at startup. Failing to do so results in errors when starting the server and during
InnoDB
recovery.When encrypting production data, ensure that you take steps to prevent loss of the master encryption key. If the master encryption key is lost, data stored in encrypted tablespace files is unrecoverable. If you use the
component_keyring_file
orcomponent_keyring_encrypted_file
component create a backup of the keyring data file immediately after creating the first encrypted tablespace, before master key rotation, and after master key rotation. For each component, its configuration file indicates the data file location. If you use thekeyring_okv
orkeyring_aws
plugin, ensure that you have performed the necessary configuration. For instructions, see Section 8.4.4, “The MySQL Keyring”.
default_table_encryption
system
variable defines the default encryption setting for schemas and
general tablespaces. CREATE
TABLESPACE
and
CREATE
SCHEMA
operations apply the
default_table_encryption
setting
when an ENCRYPTION
clause is not specified
explicitly.
ALTER
SCHEMA
and ALTER
TABLESPACE
operations do not apply the
default_table_encryption
setting.
An ENCRYPTION
clause must be specified
explicitly to alter the encryption of an existing schema or
general tablespace.
The default_table_encryption
variable can be set for an individual client connection or
globally using
SET
syntax. For example, the following statement enables default
schema and tablespace encryption globally:
mysql> SET GLOBAL default_table_encryption=ON;
The default encryption setting for a schema can also be defined
using the DEFAULT ENCRYPTION
clause when
creating or altering a schema, as in this example:
mysql> CREATE SCHEMA test DEFAULT ENCRYPTION = 'Y';
If the DEFAULT ENCRYPTION
clause is not
specified when creating a schema, the
default_table_encryption
setting
is applied. The DEFAULT ENCRYPTION
clause must
be specified to alter the default encryption of an existing
schema. Otherwise, the schema retains its current encryption
setting.
By default, a table inherits the encryption setting of the schema or general tablespace it is created in. For example, a table created in an encryption-enabled schema is encrypted by default. This behavior enables a DBA to control table encryption usage by defining and enforcing schema and general tablespace encryption defaults.
Encryption defaults are enforced by enabling the
table_encryption_privilege_check
system variable. When
table_encryption_privilege_check
is enabled, a privilege check occurs when creating or altering a
schema or general tablespace with an encryption setting that
differs from the
default_table_encryption
setting,
or when creating or altering a table with an encryption setting
that differs from the default schema encryption. When
table_encryption_privilege_check
is disabled (the default), the privilege check does not occur and
the previously mentioned operations are permitted to proceed with
a warning.
The TABLE_ENCRYPTION_ADMIN
privilege is required to override default encryption settings when
table_encryption_privilege_check
is enabled. A DBA can grant this privilege to enable a user to
deviate from the
default_table_encryption
setting
when creating or altering a schema or general tablespace, or to
deviate from the default schema encryption when creating or
altering a table. This privilege does not permit deviating from
the encryption of a general tablespace when creating or altering a
table. A table must have the same encryption setting as the
general tablespace it resides in.
A file-per-table tablespace inherits the default encryption of the
schema in which the table is created unless an
ENCRYPTION
clause is specified explicitly in
the CREATE TABLE
statement.
mysql> CREATE TABLE t1 (c1 INT) ENCRYPTION = 'Y';
To alter the encryption of an existing file-per-table tablespace,
an ENCRYPTION
clause must be specified.
mysql> ALTER TABLE t1 ENCRYPTION = 'Y';
table_encryption_privilege_check
is enabled, specifying an ENCRYPTION
clause
with a setting that differs from the default schema encryption
requires the TABLE_ENCRYPTION_ADMIN
privilege. See
Defining an Encryption Default for Schemas and General Tablespaces.
The default_table_encryption
variable determines the encryption of a newly created general
tablespace unless an ENCRYPTION
clause is
specified explicitly in the CREATE
TABLESPACE
statement.
mysql> CREATE TABLESPACE `ts1` ADD DATAFILE 'ts1.ibd' ENCRYPTION = 'Y' Engine=InnoDB;
To alter the encryption of an existing general tablespace, an
ENCRYPTION
clause must be specified.
mysql> ALTER TABLESPACE ts1 ENCRYPTION = 'Y';
If
table_encryption_privilege_check
is enabled, specifying an ENCRYPTION
clause
with a setting that differs from the
default_table_encryption
setting
requires the TABLE_ENCRYPTION_ADMIN
privilege. See
Defining an Encryption Default for Schemas and General Tablespaces.
In MySQL 9.1, InnoDB
automatically
encrypts doublewrite file pages that belong to encrypted
tablespaces. No action is required. Doublewrite file pages are
encrypted using the encryption key of the associated tablespace.
The same encrypted page written to a tablespace data file is also
written to a doublewrite file. Doublewrite file pages that belong
to an unencrypted tablespace remain unencrypted.
During recovery, encrypted doublewrite file pages are unencrypted and checked for corruption.
The mysql
system tablespace contains the
mysql
system database and MySQL data dictionary
tables. It is unencrypted by default. To enable encryption for the
mysql
system tablespace, specify the tablespace
name and the ENCRYPTION
option in an
ALTER TABLESPACE
statement.
mysql> ALTER TABLESPACE mysql ENCRYPTION = 'Y';
To disable encryption for the mysql
system
tablespace, set ENCRYPTION = 'N'
using an
ALTER TABLESPACE
statement.
mysql> ALTER TABLESPACE mysql ENCRYPTION = 'N';
Enabling or disabling encryption for the mysql
system tablespace requires the CREATE
TABLESPACE
privilege on all tables in the instance
(CREATE TABLESPACE on *.*)
.
Redo log data encryption is enabled using the
innodb_redo_log_encrypt
configuration option. Redo log encryption is disabled by default.
As with tablespace data, redo log data encryption occurs when redo log data is written to disk, and decryption occurs when redo log data is read from disk. Once redo log data is read into memory, it is in unencrypted form. Redo log data is encrypted and decrypted using the tablespace encryption key.
When innodb_redo_log_encrypt
is
enabled, unencrypted redo log pages that are present on disk
remain unencrypted, and new redo log pages are written to disk in
encrypted form. Likewise, when
innodb_redo_log_encrypt
is
disabled, encrypted redo log pages that are present on disk remain
encrypted, and new redo log pages are written to disk in
unencrypted form.
Redo log encryption metadata, including the tablespace encryption key, is stored in the header of the redo log file with the most recent checkpoint LSN. If the redo log file with the encryption metadata is removed, redo log encryption is disabled.
Once redo log encryption is enabled, a normal restart without the
keyring component or plugin or without the encryption key is not
possible, as InnoDB
must be able to scan redo
pages during startup, which is not possible if redo log pages are
encrypted. Without the keyring component or plugin or the
encryption key, only a forced startup without the redo logs
(SRV_FORCE_NO_LOG_REDO
) is possible. See
Section 17.20.3, “Forcing InnoDB Recovery”.
Undo log data encryption is enabled using the
innodb_undo_log_encrypt
configuration option. Undo log encryption applies to undo logs
that reside in undo
tablespaces. See Section 17.6.3.4, “Undo Tablespaces”.
Undo log data encryption is disabled by default.
As with tablespace data, undo log data encryption occurs when undo log data is written to disk, and decryption occurs when undo log data is read from disk. Once undo log data is read into memory, it is in unencrypted form. Undo log data is encrypted and decrypted using the tablespace encryption key.
When innodb_undo_log_encrypt
is
enabled, unencrypted undo log pages that are present on disk
remain unencrypted, and new undo log pages are written to disk in
encrypted form. Likewise, when
innodb_undo_log_encrypt
is
disabled, encrypted undo log pages that are present on disk remain
encrypted, and new undo log pages are written to disk in
unencrypted form.
Undo log encryption metadata, including the tablespace encryption key, is stored in the header of the undo log file.
When undo log encryption is disabled, the server continues to require the keyring component or plugin that was used to encrypt undo log data until the undo tablespaces that contained the encrypted undo log data are truncated. (An encryption header is only removed from an undo tablespace when the undo tablespace is truncated.) For information about truncating undo tablespaces, see Truncating Undo Tablespaces.
The master encryption key should be rotated periodically and whenever you suspect that the key has been compromised.
Master key rotation is an atomic, instance-level operation. Each
time the master encryption key is rotated, all tablespace keys in
the MySQL instance are re-encrypted and saved back to their
respective tablespace headers. As an atomic operation,
re-encryption must succeed for all tablespace keys once a rotation
operation is initiated. If master key rotation is interrupted by a
server failure, InnoDB
rolls the operation
forward on server restart. For more information, see
Encryption and Recovery.
Rotating the master encryption key only changes the master encryption key and re-encrypts tablespace keys. It does not decrypt or re-encrypt associated tablespace data.
Rotating the master encryption key requires the
ENCRYPTION_KEY_ADMIN
privilege (or
the deprecated SUPER
privilege).
To rotate the master encryption key, run:
mysql> ALTER INSTANCE ROTATE INNODB MASTER KEY;
ALTER INSTANCE ROTATE INNODB MASTER
KEY
supports concurrent DML. However, it cannot be run
concurrently with tablespace encryption operations, and locks are
taken to prevent conflicts that could arise from concurrent
execution. If an ALTER INSTANCE ROTATE INNODB
MASTER KEY
operation is running, it must finish before a
tablespace encryption operation can proceed, and vice versa.
If a server failure occurs during an encryption operation, the operation is rolled forward when the server is restarted. For general tablespaces, the encryption operation is resumed in a background thread from the last processed page.
If a server failure occurs during master key rotation,
InnoDB
continues the operation on server
restart.
The keyring component or plugin must be loaded prior to storage
engine initialization so that the information necessary to decrypt
tablespace data pages can be retrieved from tablespace headers
before InnoDB
initialization and recovery
activities access tablespace data. (See
Encryption Prerequisites.)
When InnoDB
initialization and recovery begin,
the master key rotation operation resumes. Due to the server
failure, some tablespace keys may already be encrypted using the
new master encryption key. InnoDB
reads the
encryption data from each tablespace header, and if the data
indicates that the tablespace key is encrypted using the old
master encryption key, InnoDB
retrieves the old
key from the keyring and uses it to decrypt the tablespace key.
InnoDB
then re-encrypts the tablespace key
using the new master encryption key and saves the re-encrypted
tablespace key back to the tablespace header.
Tablespace export is only supported for file-per-table tablespaces.
When an encrypted tablespace is exported,
InnoDB
generates a transfer
key that is used to encrypt the tablespace key. The
encrypted tablespace key and transfer key are stored in a
file. This file together with the encrypted tablespace file is
required to perform an import operation. On import,
tablespace_name
.cfpInnoDB
uses the transfer key to decrypt the
tablespace key in the
file. For related information, see
Section 17.6.1.3, “Importing InnoDB Tables”.
tablespace_name
.cfp
The
ALTER INSTANCE ROTATE INNODB MASTER KEY
statement is only supported in replication environments where the source and replica run a version of MySQL that supports tablespace encryption.Successful
ALTER INSTANCE ROTATE INNODB MASTER KEY
statements are written to the binary log for replication on replicas.If an
ALTER INSTANCE ROTATE INNODB MASTER KEY
statement fails, it is not logged to the binary log and is not replicated on replicas.Replication of an
ALTER INSTANCE ROTATE INNODB MASTER KEY
operation fails if the keyring component or plugin is installed on the source but not on the replica.
The Information Schema
INNODB_TABLESPACES
table includes an
ENCRYPTION
column that can be used to identify
encrypted tablespaces.
mysql> SELECT SPACE, NAME, SPACE_TYPE, ENCRYPTION FROM INFORMATION_SCHEMA.INNODB_TABLESPACES
WHERE ENCRYPTION='Y'\G
*************************** 1. row ***************************
SPACE: 4294967294
NAME: mysql
SPACE_TYPE: General
ENCRYPTION: Y
*************************** 2. row ***************************
SPACE: 2
NAME: test/t1
SPACE_TYPE: Single
ENCRYPTION: Y
*************************** 3. row ***************************
SPACE: 3
NAME: ts1
SPACE_TYPE: General
ENCRYPTION: Y
When the ENCRYPTION
option is specified in a
CREATE TABLE
or
ALTER TABLE
statement, it is
recorded in the CREATE_OPTIONS
column of
INFORMATION_SCHEMA.TABLES
. This
column can be queried to identify tables that reside in encrypted
file-per-table tablespaces.
mysql> SELECT TABLE_SCHEMA, TABLE_NAME, CREATE_OPTIONS FROM INFORMATION_SCHEMA.TABLES
WHERE CREATE_OPTIONS LIKE '%ENCRYPTION%';
+--------------+------------+----------------+
| TABLE_SCHEMA | TABLE_NAME | CREATE_OPTIONS |
+--------------+------------+----------------+
| test | t1 | ENCRYPTION="Y" |
+--------------+------------+----------------+
Query the Information Schema
INNODB_TABLESPACES
table to retrieve
information about the tablespace associated with a particular
schema and table.
mysql> SELECT SPACE, NAME, SPACE_TYPE FROM INFORMATION_SCHEMA.INNODB_TABLESPACES WHERE NAME='test/t1';
+-------+---------+------------+
| SPACE | NAME | SPACE_TYPE |
+-------+---------+------------+
| 3 | test/t1 | Single |
+-------+---------+------------+
You can identify encryption-enabled schemas by querying the
Information Schema SCHEMATA
table.
mysql> SELECT SCHEMA_NAME, DEFAULT_ENCRYPTION FROM INFORMATION_SCHEMA.SCHEMATA
WHERE DEFAULT_ENCRYPTION='YES';
+-------------+--------------------+
| SCHEMA_NAME | DEFAULT_ENCRYPTION |
+-------------+--------------------+
| test | YES |
+-------------+--------------------+
SHOW CREATE
SCHEMA
also shows the DEFAULT
ENCRYPTION
clause.
You can monitor general tablespace and mysql
system tablespace encryption progress using
Performance Schema.
The stage/innodb/alter tablespace (encryption)
stage event instrument reports WORK_ESTIMATED
and WORK_COMPLETED
information for general
tablespace encryption operations.
The following example demonstrates how to enable the
stage/innodb/alter tablespace (encryption)
stage event instrument and related consumer tables to monitor
general tablespace or mysql
system tablespace
encryption progress. For information about Performance Schema
stage event instruments and related consumers, see
Section 29.12.5, “Performance Schema Stage Event Tables”.
Enable the
stage/innodb/alter tablespace (encryption)
instrument:mysql> USE performance_schema; mysql> UPDATE setup_instruments SET ENABLED = 'YES' WHERE NAME LIKE 'stage/innodb/alter tablespace (encryption)';
Enable the stage event consumer tables, which include
events_stages_current
,events_stages_history
, andevents_stages_history_long
.mysql> UPDATE setup_consumers SET ENABLED = 'YES' WHERE NAME LIKE '%stages%';
Run a tablespace encryption operation. In this example, a general tablespace named
ts1
is encrypted.mysql> ALTER TABLESPACE ts1 ENCRYPTION = 'Y';
Check the progress of the encryption operation by querying the Performance Schema
events_stages_current
table.WORK_ESTIMATED
reports the total number of pages in the tablespace.WORK_COMPLETED
reports the number of pages processed.mysql> SELECT EVENT_NAME, WORK_ESTIMATED, WORK_COMPLETED FROM events_stages_current; +--------------------------------------------+----------------+----------------+ | EVENT_NAME | WORK_COMPLETED | WORK_ESTIMATED | +--------------------------------------------+----------------+----------------+ | stage/innodb/alter tablespace (encryption) | 1056 | 1407 | +--------------------------------------------+----------------+----------------+
The
events_stages_current
table returns an empty set if the encryption operation has completed. In this case, you can check theevents_stages_history
table to view event data for the completed operation. For example:mysql> SELECT EVENT_NAME, WORK_COMPLETED, WORK_ESTIMATED FROM events_stages_history; +--------------------------------------------+----------------+----------------+ | EVENT_NAME | WORK_COMPLETED | WORK_ESTIMATED | +--------------------------------------------+----------------+----------------+ | stage/innodb/alter tablespace (encryption) | 1407 | 1407 | +--------------------------------------------+----------------+----------------+
Plan appropriately when altering an existing file-per-table tablespace with the
ENCRYPTION
option. Tables residing in file-per-table tablespaces are rebuilt using theCOPY
algorithm. TheINPLACE
algorithm is used when altering theENCRYPTION
attribute of a general tablespace or themysql
system tablespace. TheINPLACE
algorithm permits concurrent DML on tables that reside in the general tablespace. Concurrent DDL is blocked.When a general tablespace or the
mysql
system tablespace is encrypted, all tables residing in the tablespace are encrypted. Likewise, a table created in an encrypted tablespace is encrypted.If the server exits or is stopped during normal operation, it is recommended to restart the server using the same encryption settings that were configured previously.
The first master encryption key is generated when the first new or existing tablespace is encrypted.
Master key rotation re-encrypts tablespaces keys but does not change the tablespace key itself. To change a tablespace key, you must disable and re-enable encryption. For file-per-table tablespaces, re-encrypting the tablespace is an
ALGORITHM=COPY
operation that rebuilds the table. For general tablespaces and themysql
system tablespace, it is anALGORITHM=INPLACE
operation, which does not require rebuilding tables that reside in the tablespace.If a table is created with both the
COMPRESSION
andENCRYPTION
options, compression is performed before tablespace data is encrypted.Uninstalling the
component_keyring_file
orcomponent_keyring_encrypted_file
component does not remove an existing keyring data file.It is recommended that you not place a keyring data file under the same directory as tablespace data files.
Encryption is supported for the
InnoDB
FULLTEXT
index tables that are created implicitly when adding aFULLTEXT
index. For related information, see InnoDB Full-Text Index Tables.
Advanced Encryption Standard (AES) is the only supported encryption algorithm.
InnoDB
tablespace encryption uses Electronic Codebook (ECB) block encryption mode for tablespace key encryption and Cipher Block Chaining (CBC) block encryption mode for data encryption. Padding is not used with CBC block encryption mode. Instead,InnoDB
ensures that the text to be encrypted is a multiple of the block size.Encryption is supported only for file-per-table tablespaces, general tablespaces, and the
mysql
system tablespace. Encryption is not supported for other tablespace types including theInnoDB
system tablespace.You cannot move or copy a table from an encrypted file-per-table tablespace, general tablespace, or the
mysql
system tablespace to a tablespace type that does not support encryption.You cannot move or copy a table from an encrypted tablespace to an unencrypted tablespace. However, moving a table from an unencrypted tablespace to an encrypted one is permitted. For example, you can move or copy a table from a unencrypted file-per-table or general tablespace to an encrypted general tablespace.
By default, tablespace encryption only applies to data in the tablespace. Redo log and undo log data can be encrypted by enabling
innodb_redo_log_encrypt
andinnodb_undo_log_encrypt
. See Redo Log Encryption, and Undo Log Encryption. For information about binary log file and relay log file encryption, see Section 19.3.2, “Encrypting Binary Log Files and Relay Log Files”.It is not permitted to change the storage engine of a table that resides in, or previously resided in, an encrypted tablespace.