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15.10 InnoDB Row Formats
The row format of a table determines how its rows are physically stored, which in turn can affect the performance of queries and DML operations. As more rows fit into a single disk page, queries and index lookups can work faster, less cache memory is required in the buffer pool, and less I/O is required to write out updated values.
The data in each table is divided into pages. The pages that make up each table are arranged in a tree data structure called a B-tree index. Table data and secondary indexes both use this type of structure. The B-tree index that represents an entire table is known as the clustered index, which is organized according to the primary key columns. The nodes of a clustered index data structure contain the values of all columns in the row. The nodes of a secondary index structure contain the values of index columns and primary key columns.
Variable-length columns are an exception to the rule that column values are stored in B-tree index nodes. Variable-length columns that are too long to fit on a B-tree page are stored on separately allocated disk pages called overflow pages. Such columns are referred to as off-page columns. The values of off-page columns are stored in singly-linked lists of overflow pages, with each such column having its own list of one or more overflow pages. Depending on column length, all or a prefix of variable-length column values are stored in the B-tree to avoid wasting storage and having to read a separate page.
The InnoDB
storage engine supports four row
formats: REDUNDANT
, COMPACT
,
DYNAMIC
, and COMPRESSED
.
Table 15.16 InnoDB Row Format Overview
Row Format | Compact Storage Characteristics | Enhanced Variable-Length Column Storage | Large Index Key Prefix Support | Compression Support | Supported Tablespace Types |
---|---|---|---|---|---|
REDUNDANT |
No | No | No | No | system, file-per-table, general |
COMPACT |
Yes | No | No | No | system, file-per-table, general |
DYNAMIC |
Yes | Yes | Yes | No | system, file-per-table, general |
COMPRESSED |
Yes | Yes | Yes | Yes | file-per-table, general |
The topics that follow describe row format storage characteristics and how to define and determine the row format of a table.
REDUNDANT Row Format
The REDUNDANT
format provides compatibility
with older versions of MySQL.
Tables that use the REDUNDANT
row format store
the first 768 bytes of variable-length column values
(VARCHAR
,
VARBINARY
, and
BLOB
and
TEXT
types) in the index record
within the B-tree node, with the remainder stored on overflow
pages. Fixed-length columns greater than or equal to 768 bytes are
encoded as variable-length columns, which can be stored off-page.
For example, a CHAR(255)
column can exceed 768
bytes if the maximum byte length of the character set is greater
than 3, as it is with utf8mb4
.
If the value of a column is 768 bytes or less, an overflow page is
not used, and some savings in I/O may result, since the value is
stored entirely in the B-tree node. This works well for relatively
short BLOB
column values, but may cause B-tree
nodes to fill with data rather than key values, reducing their
efficiency. Tables with many BLOB
columns could
cause B-tree nodes to become too full, and contain too few rows,
making the entire index less efficient than if rows were shorter
or column values were stored off-page.
REDUNDANT Row Format Storage Characteristics
The REDUNDANT
row format has the following
storage characteristics:
Each index record contains a 6-byte header. The header is used to link together consecutive records, and for row-level locking.
Records in the clustered index contain fields for all user-defined columns. In addition, there is a 6-byte transaction ID field and a 7-byte roll pointer field.
If no primary key is defined for a table, each clustered index record also contains a 6-byte row ID field.
Each secondary index record contains all the primary key columns defined for the clustered index key that are not in the secondary index.
A record contains a pointer to each field of the record. If the total length of the fields in a record is less than 128 bytes, the pointer is one byte; otherwise, two bytes. The array of pointers is called the record directory. The area where the pointers point is the data part of the record.
Internally, fixed-length character columns such as
CHAR(10)
in stored in fixed-length format. Trailing spaces are not truncated fromVARCHAR
columns.Fixed-length columns greater than or equal to 768 bytes are encoded as variable-length columns, which can be stored off-page. For example, a
CHAR(255)
column can exceed 768 bytes if the maximum byte length of the character set is greater than 3, as it is withutf8mb4
.An SQL
NULL
value reserves one or two bytes in the record directory. An SQLNULL
value reserves zero bytes in the data part of the record if stored in a variable-length column. For a fixed-length column, the fixed length of the column is reserved in the data part of the record. Reserving fixed space forNULL
values permits columns to be updated in place fromNULL
to non-NULL
values without causing index page fragmentation.
The COMPACT
row format reduces row storage
space by about 20% compared to the REDUNDANT
row format, at the cost of increasing CPU use for some operations.
If your workload is a typical one that is limited by cache hit
rates and disk speed, COMPACT
format is likely
to be faster. If the workload is limited by CPU speed, compact
format might be slower.
Tables that use the COMPACT
row format store
the first 768 bytes of variable-length column values
(VARCHAR
,
VARBINARY
, and
BLOB
and
TEXT
types) in the index record
within the B-tree node, with
the remainder stored on overflow pages. Fixed-length columns
greater than or equal to 768 bytes are encoded as variable-length
columns, which can be stored off-page. For example, a
CHAR(255)
column can exceed 768 bytes if the
maximum byte length of the character set is greater than 3, as it
is with utf8mb4
.
If the value of a column is 768 bytes or less, an overflow page is
not used, and some savings in I/O may result, since the value is
stored entirely in the B-tree node. This works well for relatively
short BLOB
column values, but may cause B-tree
nodes to fill with data rather than key values, reducing their
efficiency. Tables with many BLOB
columns could
cause B-tree nodes to become too full, and contain too few rows,
making the entire index less efficient than if rows were shorter
or column values were stored off-page.
COMPACT Row Format Storage Characteristics
The COMPACT
row format has the following
storage characteristics:
Each index record contains a 5-byte header that may be preceded by a variable-length header. The header is used to link together consecutive records, and for row-level locking.
The variable-length part of the record header contains a bit vector for indicating
NULL
columns. If the number of columns in the index that can beNULL
isN
, the bit vector occupiesCEILING(
bytes. (For example, if there are anywhere from 9 to 16 columns that can beN
/8)NULL
, the bit vector uses two bytes.) Columns that areNULL
do not occupy space other than the bit in this vector. The variable-length part of the header also contains the lengths of variable-length columns. Each length takes one or two bytes, depending on the maximum length of the column. If all columns in the index areNOT NULL
and have a fixed length, the record header has no variable-length part.For each non-
NULL
variable-length field, the record header contains the length of the column in one or two bytes. Two bytes are only needed if part of the column is stored externally in overflow pages or the maximum length exceeds 255 bytes and the actual length exceeds 127 bytes. For an externally stored column, the 2-byte length indicates the length of the internally stored part plus the 20-byte pointer to the externally stored part. The internal part is 768 bytes, so the length is 768+20. The 20-byte pointer stores the true length of the column.The record header is followed by the data contents of non-
NULL
columns.Records in the clustered index contain fields for all user-defined columns. In addition, there is a 6-byte transaction ID field and a 7-byte roll pointer field.
If no primary key is defined for a table, each clustered index record also contains a 6-byte row ID field.
Each secondary index record contains all the primary key columns defined for the clustered index key that are not in the secondary index. If any of the primary key columns are variable length, the record header for each secondary index has a variable-length part to record their lengths, even if the secondary index is defined on fixed-length columns.
Internally, for nonvariable-length character sets, fixed-length character columns such as
CHAR(10)
are stored in a fixed-length format.Trailing spaces are not truncated from
VARCHAR
columns.Internally, for variable-length character sets such as
utf8mb3
andutf8mb4
,InnoDB
attempts to storeCHAR(
inN
)N
bytes by trimming trailing spaces. If the byte length of aCHAR(
column value exceedsN
)N
bytes, trailing spaces are trimmed to a minimum of the column value byte length. The maximum length of aCHAR(
column is the maximum character byte length ×N
)N
.A minimum of
N
bytes is reserved forCHAR(
. Reserving the minimum spaceN
)N
in many cases enables column updates to be done in place without causing index page fragmentation. By comparison,CHAR(
columns occupy the maximum character byte length ×N
)N
when using theREDUNDANT
row format.Fixed-length columns greater than or equal to 768 bytes are encoded as variable-length fields, which can be stored off-page. For example, a
CHAR(255)
column can exceed 768 bytes if the maximum byte length of the character set is greater than 3, as it is withutf8mb4
.
The DYNAMIC
row format offers the same storage
characteristics as the COMPACT
row format but
adds enhanced storage capabilities for long variable-length
columns and supports large index key prefixes.
When a table is created with
ROW_FORMAT=DYNAMIC
, InnoDB
can store long variable-length column values (for
VARCHAR
,
VARBINARY
, and
BLOB
and
TEXT
types) fully off-page, with
the clustered index record containing only a 20-byte pointer to
the overflow page. Fixed-length fields greater than or equal to
768 bytes are encoded as variable-length fields. For example, a
CHAR(255)
column can exceed 768 bytes if the
maximum byte length of the character set is greater than 3, as it
is with utf8mb4
.
Whether columns are stored off-page depends on the page size and
the total size of the row. When a row is too long, the longest
columns are chosen for off-page storage until the clustered index
record fits on the B-tree page.
TEXT
and
BLOB
columns that are less than or
equal to 40 bytes are stored in line.
The DYNAMIC
row format maintains the efficiency
of storing the entire row in the index node if it fits (as do the
COMPACT
and REDUNDANT
formats), but the DYNAMIC
row format avoids the
problem of filling B-tree nodes with a large number of data bytes
of long columns. The DYNAMIC
row format is
based on the idea that if a portion of a long data value is stored
off-page, it is usually most efficient to store the entire value
off-page. With DYNAMIC
format, shorter columns
are likely to remain in the B-tree node, minimizing the number of
overflow pages required for a given row.
The DYNAMIC
row format supports index key
prefixes up to 3072 bytes.
Tables that use the DYNAMIC
row format can be
stored in the system tablespace, file-per-table tablespaces, and
general tablespaces. To store DYNAMIC
tables in
the system tablespace, either disable
innodb_file_per_table
and use a
regular CREATE TABLE
or ALTER
TABLE
statement, or use the TABLESPACE [=]
innodb_system
table option with CREATE
TABLE
or ALTER TABLE
. The
innodb_file_per_table
variable is
not applicable to general tablespaces, nor is it applicable when
using the TABLESPACE [=] innodb_system
table
option to store DYNAMIC
tables in the system
tablespace.
DYNAMIC Row Format Storage Characteristics
The DYNAMIC
row format is a variation of the
COMPACT
row format. For storage
characteristics, see
COMPACT Row Format Storage Characteristics.
The COMPRESSED
row format offers the same
storage characteristics and capabilities as the
DYNAMIC
row format but adds support for table
and index data compression.
The COMPRESSED
row format uses similar internal
details for off-page storage as the DYNAMIC
row
format, with additional storage and performance considerations
from the table and index data being compressed and using smaller
page sizes. With the COMPRESSED
row format, the
KEY_BLOCK_SIZE
option controls how much column
data is stored in the clustered index, and how much is placed on
overflow pages. For more information about the
COMPRESSED
row format, see
Section 15.9, “InnoDB Table and Page Compression”.
The COMPRESSED
row format supports index key
prefixes up to 3072 bytes.
Tables that use the COMPRESSED
row format can
be created in file-per-table tablespaces or general tablespaces.
The system tablespace does not support the
COMPRESSED
row format. To store a
COMPRESSED
table in a file-per-table
tablespace, the
innodb_file_per_table
variable
must be enabled. The
innodb_file_per_table
variable is
not applicable to general tablespaces. General tablespaces support
all row formats with the caveat that compressed and uncompressed
tables cannot coexist in the same general tablespace due to
different physical page sizes. For more information, see
Section 15.6.3.3, “General Tablespaces”.
Compressed Row Format Storage Characteristics
The COMPRESSED
row format is a variation of the
COMPACT
row format. For storage
characteristics, see
COMPACT Row Format Storage Characteristics.
The default row format for InnoDB
tables is
defined by
innodb_default_row_format
variable, which has a default value of DYNAMIC
.
The default row format is used when the
ROW_FORMAT
table option is not defined
explicitly or when ROW_FORMAT=DEFAULT
is
specified.
The row format of a table can be defined explicitly using the
ROW_FORMAT
table option in a
CREATE TABLE
or
ALTER TABLE
statement. For example:
An explicitly defined ROW_FORMAT
setting
overrides the default row format. Specifying
ROW_FORMAT=DEFAULT
is equivalent to using the
implicit default.
The innodb_default_row_format
variable can be set dynamically:
Valid innodb_default_row_format
options include DYNAMIC
,
COMPACT
, and REDUNDANT
. The
COMPRESSED
row format, which is not supported
for use in the system tablespace, cannot be defined as the
default. It can only be specified explicitly in a
CREATE TABLE
or
ALTER TABLE
statement. Attempting
to set the
innodb_default_row_format
variable to COMPRESSED
returns an error:
- ERROR 1231 (42000): Variable 'innodb_default_row_format'
- can't be set to the value of 'COMPRESSED'
Newly created tables use the row format defined by the
innodb_default_row_format
variable when a ROW_FORMAT
option is not
specified explicitly, or when
ROW_FORMAT=DEFAULT
is used. For example, the
following CREATE TABLE
statements
use the row format defined by the
innodb_default_row_format
variable.
When a ROW_FORMAT
option is not specified
explicitly, or when ROW_FORMAT=DEFAULT
is used,
an operation that rebuilds a table silently changes the row format
of the table to the format defined by the
innodb_default_row_format
variable.
Table-rebuilding operations include ALTER
TABLE
operations that use
ALGORITHM=COPY
or
ALGORITHM=INPLACE
where table rebuilding is
required. See Section 15.12.1, “Online DDL Operations” for
more information. OPTIMIZE TABLE
is
also a table-rebuilding operation.
The following example demonstrates a table-rebuilding operation that silently changes the row format of a table created without an explicitly defined row format.
- +-----------------------------+
- | @@innodb_default_row_format |
- +-----------------------------+
- | dynamic |
- +-----------------------------+
- *************************** 1. row ***************************
- TABLE_ID: 54
- NAME: test/t1
- FLAG: 33
- N_COLS: 4
- SPACE: 35
- ROW_FORMAT: Dynamic
- ZIP_PAGE_SIZE: 0
- SPACE_TYPE: Single
- *************************** 1. row ***************************
- TABLE_ID: 55
- NAME: test/t1
- FLAG: 1
- N_COLS: 5
- SPACE: 36
- ROW_FORMAT: Compact
- ZIP_PAGE_SIZE: 0
- SPACE_TYPE: Single
Consider the following potential issues before changing the row
format of existing tables from REDUNDANT
or
COMPACT
to DYNAMIC
.
The
REDUNDANT
andCOMPACT
row formats support a maximum index key prefix length of 767 bytes whereasDYNAMIC
andCOMPRESSED
row formats support an index key prefix length of 3072 bytes. In a replication environment, if theinnodb_default_row_format
variable is set toDYNAMIC
on the master, and set toCOMPACT
on the slave, the following DDL statement, which does not explicitly define a row format, succeeds on the master but fails on the slave:For related information, see Section 15.6.1.6, “Limits on InnoDB Tables”.
Importing a table that does not explicitly define a row format results in a schema mismatch error if the
innodb_default_row_format
setting on the source server differs from the setting on the destination server. For more information, refer to the limitations outlined in Section 15.6.3.7, “Copying Tablespaces to Another Instance”.
To determine the row format of a table, use
SHOW TABLE STATUS
:
- *************************** 1. row ***************************
- Name: t1
- Version: 10
- Row_format: Dynamic
- Rows: 0
- Data_length: 16384
- Max_data_length: 0
- Index_length: 16384
- Data_free: 0
- Create_time: 2016-09-14 16:29:38
- Update_time: NULL
- Check_time: NULL
- Collation: utf8mb4_0900_ai_ci
- Create_options:
Alternatively, query the
INFORMATION_SCHEMA.INNODB_TABLES
table:
- +----------+------------+
- +----------+------------+
- | test1/t1 | Dynamic |
- +----------+------------+
Document created the 26/06/2006, last modified the 26/10/2018
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