Skip Headers

Oracle9i Database Concepts
Release 2 (9.2)

Part Number A96524-01
Go To Documentation Library
Home
Go To Product List
Book List
Go To Table Of Contents
Contents
Go To Index
Index

Master Index

Feedback

Go to previous page Go to next page

11
Partitioned Tables and Indexes

This chapter describes partitioned tables and indexes. It covers the following topics:

Introduction to Partitioning

Partitioning addresses key issues in supporting very large tables and indexes by letting you decompose them into smaller and more manageable pieces called partitions. SQL queries and DML statements do not need to be modified in order to access partitioned tables. However, after partitions are defined, DDL statements can access and manipulate individuals partitions rather than entire tables or indexes. This is how partitioning can simplify the manageability of large database objects. Also, partitioning is entirely transparent to applications.

Each partition of a table or index must have the same logical attributes, such as column names, datatypes, and constraints, but each partition can have separate physical attributes such as pctfree, pctused, and tablespaces.

Partitioning is useful for many different types of applications, particularly applications that manage large volumes of data. OLTP systems often benefit from improvements in manageability and availability, while data warehousing systems benefit from performance and manageability.


Note:

All partitions of a partitioned object must reside in tablespaces of a single block size.


See Also:

Partitioning offers these advantages:

Figure 11-1 offers a graphical view of how partitioned tables differ from nonpartitioned tables.

Figure 11-1 A View of Partitioned Tables

Text description of cncpt162.gif follows
Text description of the illustration cncpt162.gif


Partition Key

Each row in a partitioned table is unambiguously assigned to a single partition. The partition key is a set of one or more columns that determines the partition for each row. Oracle9i automatically directs insert, update, and delete operations to the appropriate partition through the use of the partition key. A partition key:

Partitioned Tables

Tables can be partitioned into up to 64,000 separate partitions. Any table can be partitioned except those tables containing columns with LONG or LONG RAW datatypes. You can, however, use tables containing columns with CLOB or BLOB datatypes.

Partitioned Index-Organized Tables

You can range partition index-organized tables. This feature is very useful for providing improved manageability, availability and performance for index-organized tables. In addition, data cartridges that use index-organized tables can take advantage of the ability to partition their stored data. Common examples of this are the Image and interMedia cartridges.

For partitioning an index-organized table:

Partitioning Methods

Oracle provides the following partitioning methods:

Figure 11-2 offers a graphical view of the methods of partitioning.

Figure 11-2 List, Range, and Hash Partitioning

Text description of cncpt158.gif follows
Text description of the illustration cncpt158.gif


Composite partitioning is a combination of other partitioning methods. Oracle currently supports range-hash and range-list composite partitioning. Figure 11-3 offers a graphical view of range-hash and range-list composite partitioning.

Figure 11-3 Composite Partitioning

Text description of cncpt168.gif follows
Text description of the illustration cncpt168.gif


Range Partitioning

Range partitioning maps data to partitions based on ranges of partition key values that you establish for each partition. It is the most common type of partitioning and is often used with dates. For example, you might want to partition sales data into monthly partitions.

When using range partitioning, consider the following rules:

A typical example is given in the following section. The statement creates a table (sales_range) that is range partitioned on the sales_date field.

Range Partitioning Example

CREATE TABLE sales_range 
(salesman_id  NUMBER(5), 
salesman_name VARCHAR2(30), 
sales_amount  NUMBER(10), 
sales_date    DATE)
PARTITION BY RANGE(sales_date) 
(
PARTITION sales_jan2000 VALUES LESS THAN(TO_DATE('02/01/2000','DD/MM/YYYY')),
PARTITION sales_feb2000 VALUES LESS THAN(TO_DATE('03/01/2000','DD/MM/YYYY')),
PARTITION sales_mar2000 VALUES LESS THAN(TO_DATE('04/01/2000','DD/MM/YYYY')),
PARTITION sales_apr2000 VALUES LESS THAN(TO_DATE('05/01/2000','DD/MM/YYYY'))
);

List Partitioning

List partitioning enables you to explicitly control how rows map to partitions. You do this by specifying a list of discrete values for the partitioning key in the description for each partition. This is different from range partitioning, where a range of values is associated with a partition and from hash partitioning, where a hash function controls the row-to-partition mapping. The advantage of list partitioning is that you can group and organize unordered and unrelated sets of data in a natural way.

The details of list partitioning can best be described with an example. In this case, let's say you want to partition a sales table by region. That means grouping states together according to their geographical location as in the following example.

List Partitioning Example

CREATE TABLE sales_list
(salesman_id  NUMBER(5), 
salesman_name VARCHAR2(30),
sales_state   VARCHAR2(20),
sales_amount  NUMBER(10), 
sales_date    DATE)
PARTITION BY LIST(sales_state)
(
PARTITION sales_west VALUES('California', 'Hawaii'),
PARTITION sales_east VALUES ('New York', 'Virginia', 'Florida'),
PARTITION sales_central VALUES('Texas', 'Illinois')
PARTITION sales_other VALUES(DEFAULT)
);

A row is mapped to a partition by checking whether the value of the partitioning column for a row falls within the set of values that describes the partition. For example, the rows are inserted as follows:

Unlike range and hash partitioning, multicolumn partition keys are not supported for list partitioning. If a table is partitioned by list, the partitioning key can only consist of a single column of the table.

The DEFAULT partition enables you to avoid specifying all possible values for a list-partitioned table by using a default partition, so that all rows that do not map to any other partition do not generate an error.

Hash Partitioning

Hash partitioning enables easy partitioning of data that does not lend itself to range or list partitioning. It does this with a simple syntax and is easy to implement. It is a better choice than range partitioning when:

The concepts of splitting, dropping or merging partitions do not apply to hash partitions. Instead, hash partitions can be added and coalesced.

Hash Partitioning Example

CREATE TABLE sales_hash
(salesman_id  NUMBER(5), 
salesman_name VARCHAR2(30), 
sales_amount  NUMBER(10), 
week_no       NUMBER(2)) 
PARTITION BY HASH(salesman_id) 
PARTITIONS 4 
STORE IN (data1, data2, data3, data4);

The preceding statement creates a table sales_hash, which is hash partitioned on salesman_id field. The tablespace names are data1, data2, data3, and data4.

Composite Partitioning

Composite partitioning partitions data using the range method, and within each partition, subpartitions it using the hash or list method. Composite range-hash partitioning provides the improved manageability of range partitioning and the data placement, striping, and parallelism advantages of hash partitioning. Composite range-list partitioning provides the manageability of range partitioning and the explicit control of list partitioning for the subpartitions.

Composite partitioning supports historical operations, such as adding new range partitions, but also provides higher degrees of parallelism for DML operations and finer granularity of data placement through subpartitioning.

Composite Partitioning Range-Hash Example

CREATE TABLE sales_composite 
(salesman_id  NUMBER(5), 
 salesman_name VARCHAR2(30), 
 sales_amount  NUMBER(10), 
 sales_date    DATE)
PARTITION BY RANGE(sales_date) 
SUBPARTITION BY HASH(salesman_id)
SUBPARTITION TEMPLATE(
SUBPARTITION sp1 TABLESPACE data1,
SUBPARTITION sp2 TABLESPACE data2,
SUBPARTITION sp3 TABLESPACE data3,
SUBPARTITION sp4 TABLESPACE data4)
(PARTITION sales_jan2000 VALUES LESS THAN(TO_DATE('02/01/2000','DD/MM/YYYY'))
 PARTITION sales_feb2000 VALUES LESS THAN(TO_DATE('03/01/2000','DD/MM/YYYY'))
 PARTITION sales_mar2000 VALUES LESS THAN(TO_DATE('04/01/2000','DD/MM/YYYY'))
 PARTITION sales_apr2000 VALUES LESS THAN(TO_DATE('05/01/2000','DD/MM/YYYY'))
 PARTITION sales_may2000 VALUES LESS THAN(TO_DATE('06/01/2000','DD/MM/YYYY')));

This statement creates a table sales_composite that is range partitioned on the sales_date field and hash subpartitioned on salesman_id. When you use a template, Oracle names the subpartitions by concatenating the partition name, an underscore, and the subpartition name from the template. Oracle places this subpartition in the tablespace specified in the template. In the previous statement, sales_jan2000_sp1 is created and placed in tablespace data1 while sales_jan2000_sp4 is created and placed in tablespace data4. In the same manner, sales_apr2000_sp1 is created and placed in tablespace data1 while sales_apr2000_sp4 is created and placed in tablespace data4. Figure 11-4 offers a graphical view of the previous example.

Figure 11-4 Composite Range-Hash Partitioning

Text description of cncpt157.gif follows
Text description of the illustration cncpt157.gif


Composite Partitioning Range-List Example

CREATE TABLE bimonthly_regional_sales
(deptno NUMBER, 
 item_no VARCHAR2(20),
 txn_date DATE, 
 txn_amount NUMBER, 
 state VARCHAR2(2))
PARTITION BY RANGE (txn_date)
SUBPARTITION BY LIST (state)
SUBPARTITION TEMPLATE(


SUBPARTITION east VALUES('NY', 'VA', 'FL') TABLESPACE ts1,
SUBPARTITION west VALUES('CA', 'OR', 'HI') TABLESPACE ts2,
SUBPARTITION central VALUES('IL', 'TX', 'MO') TABLESPACE ts3)
( PARTITION janfeb_2000 VALUES LESS THAN (TO_DATE('1-MAR-2000','DD-MON-YYYY')), PARTITION marapr_2000 VALUES LESS THAN (TO_DATE('1-MAY-2000','DD-MON-YYYY')), PARTITION mayjun_2000 VALUES LESS THAN (TO_DATE('1-JUL-2000','DD-MON-YYYY')) );

This statement creates a table bimonthly_regional_sales that is range partitioned on the txn_date field and list subpartitioned on state. When you use a template, Oracle names the subpartitions by concatenating the partition name, an underscore, and the subpartition name from the template. Oracle places this subpartition in the tablespace specified in the template. In the previous statement, janfeb_2000_east is created and placed in tablespace ts1 while janfeb_2000_central is created and placed in tablespace ts3. In the same manner, mayjun_2000_east is placed in tablespace ts1 while mayjun_2000_central is placed in tablespace ts3. Figure 11-5 offers a graphical view of the table bimonthly_regional_sales and its 9 individual subpartitions.

Figure 11-5 Composite Range-List Partitioning

Text description of cncpt167.gif follows
Text description of the illustration cncpt167.gif


When to Partition a Table

Here are some suggestions for when to partition a table:

Partitioned Indexes

Just like partitioned tables, partitioned indexes improve manageability, availability, performance, and scalability. They can either be partitioned independently (global indexes) or automatically linked to a table's partitioning method (local indexes).

See Also:

Oracle9i Data Warehousing Guide for more information about partitioned indexes

Local Partitioned Indexes

Local partitioned indexes are easier to manage than other types of partitioned indexes. They also offer greater availability and are common in DSS environments. The reason for this is equipartitioning: each partition of a local index is associated with exactly one partition of the table. This enables Oracle to automatically keep the index partitions in sync with the table partitions, and makes each table-index pair independent. Any actions that make one partition's data invalid or unavailable only affect a single partition.

You cannot explicitly add a partition to a local index. Instead, new partitions are added to local indexes only when you add a partition to the underlying table. Likewise, you cannot explicitly drop a partition from a local index. Instead, local index partitions are dropped only when you drop a partition from the underlying table.

A local index can be unique. However, in order for a local index to be unique, the partitioning key of the table must be part of the index's key columns. Unique local indexes are useful for OLTP environments.

Figure 11-6 offers a graphical view of local partitioned indexes.

Figure 11-6 Local Partitioned Index

Text description of cncpt161.gif follows
Text description of the illustration cncpt161.gif


Global Partitioned Indexes

Global partitioned indexes are flexible in that the degree of partitioning and the partitioning key are independent from the table's partitioning method. They are commonly used for OLTP environments and offer efficient access to any individual record.

The highest partition of a global index must have a partition bound, all of whose values are MAXVALUE. This ensures that all rows in the underlying table can be represented in the index. Global prefixed indexes can be unique or nonunique.

You cannot add a partition to a global index because the highest partition always has a partition bound of MAXVALUE. If you wish to add a new highest partition, use the ALTER INDEX SPLIT PARTITION statement. If a global index partition is empty, you can explicitly drop it by issuing the ALTER INDEX DROP PARTITION statement. If a global index partition contains data, dropping the partition causes the next highest partition to be marked unusable. You cannot drop the highest partition in a global index.

Maintenance of Global Partitioned Indexes

By default, the following operations on partitions on a heap-organized table mark all global indexes as unusable:

ADD (HASH) 
COALESCE (HASH) 
DROP 
EXCHANGE 
MERGE 
MOVE 
SPLIT 
TRUNCATE 

These indexes can be maintained by appending the clause UPDATE GLOBAL INDEXES to the SQL statements for the operation. The two advantages to maintaining global indexes:

Example:
ALTER TABLE DROP PARTITION P1 UPDATE GLOBAL INDEXES


Note:

This feature is supported only for heap organized tables.


See Also:

Oracle9i SQL Reference for more information about the UPDATE GLOBAL INDEX clause

Figure 11-7 offers a graphical view of global partitioned indexes.

Figure 11-7 Global Partitioned Index

Text description of cncpt160.gif follows
Text description of the illustration cncpt160.gif


Global Nonpartitioned Indexes

Global nonpartitioned indexes behave just like a nonpartitioned index. They are commonly used in OLTP environments and offer efficient access to any individual record.

Figure 11-8 offers a graphical view of global nonpartitioned indexes.

Figure 11-8 Global Nonpartitioned Index

Text description of cncpt159.gif follows
Text description of the illustration cncpt159.gif


Partitioned Index Examples

Example of Index Creation: Starting Table Used for Examples

CREATE TABLE employees
(employee_id NUMBER(4) NOT NULL,
 last_name VARCHAR2(10), 
 department_id NUMBER(2))
PARTITION BY RANGE (department_id)
(PARTITION employees_part1 VALUES LESS THAN (11) TABLESPACE part1, 
 PARTITION employees_part2 VALUES LESS THAN (21) TABLESPACE part2, 
 PARTITION employees_part3 VALUES LESS THAN (31) TABLESPACE part3);

Example of a Local Index Creation

CREATE INDEX employees_local_idx ON employees (employee_id) LOCAL;

Example of a Global Index Creation

CREATE INDEX employees_global_idx ON employees(employee_id);

Example of a Global Partitioned Index Creation

CREATE INDEX employees_global_part_idx ON employees(employee_id)
GLOBAL PARTITION BY RANGE(employee_id)
(PARTITION p1 VALUES LESS THAN(5000),
 PARTITION p2 VALUES LESS THAN(MAXVALUE));

Example of a Partitioned Index-Organized Table Creation

CREATE TABLE sales_range
(
salesman_id   NUMBER(5), 
salesman_name VARCHAR2(30), 
sales_amount  NUMBER(10), 
sales_date    DATE, 
PRIMARY KEY(sales_date, salesman_id)) 
ORGANIZATION INDEX INCLUDING salesman_id 
OVERFLOW TABLESPACE tabsp_overflow 
PARTITION BY RANGE(sales_date)
(PARTITION sales_jan2000 VALUES LESS THAN(TO_DATE('02/01/2000','DD/MM/YYYY'))
 OVERFLOW TABLESPACE p1_overflow, 
 PARTITION sales_feb2000 VALUES LESS THAN(TO_DATE('03/01/2000','DD/MM/YYYY'))
 OVERFLOW TABLESPACE p2_overflow, 
 PARTITION sales_mar2000 VALUES LESS THAN(TO_DATE('04/01/2000','DD/MM/YYYY'))
 OVERFLOW TABLESPACE p3_overflow, 
 PARTITION sales_apr2000 VALUES LESS THAN(TO_DATE('05/01/2000','DD/MM/YYYY'))
 OVERFLOW TABLESPACE p4_overflow);

Miscellaneous Information about Creating Indexes on Partitioned Tables

You can create bitmap indexes on partitioned tables, with the restriction that the bitmap indexes must be local to the partitioned table. They cannot be global indexes.

Global indexes can be unique. Local indexes can only be unique if the partitioning key is a part of the index key.

Using Partitioned Indexes in OLTP Applications

Here are a few guidelines for OLTP applications:

Using Partitioned Indexes in Data Warehousing and DSS Applications

Here are a few guidelines for data warehousing and DSS applications:

Partitioned Indexes on Composite Partitions

Here are a few points to remember when using partitioned indexes on composite partitions:

Partitioning to Improve Performance

Partitioning can help you improve performance and manageability. Some topics to keep in mind when using partitioning for these reasons are:

Partition Pruning

The Oracle server explicitly recognizes partitions and subpartitions. It then optimizes SQL statements to mark the partitions or subpartitions that need to be accessed and eliminates (prunes) unnecessary partitions or subpartitions from access by those SQL statements. In other words, partition pruning is the skipping of unnecessary index and data partitions or subpartitions in a query.

For each SQL statement, depending on the selection criteria specified, unneeded partitions or subpartitions can be eliminated. For example, if a query only involves March sales data, then there is no need to retrieve data for the remaining eleven months. Such intelligent pruning can dramatically reduce the data volume, resulting in substantial improvements in query performance.

If the optimizer determines that the selection criteria used for pruning are satisfied by all the rows in the accessed partition or subpartition, it removes those criteria from the predicate list (WHERE clause) during evaluation in order to improve performance. However, the optimizer cannot prune partitions if the SQL statement applies a function to the partitioning column (with the exception of the TO_DATE function). Similarly, the optimizer cannot use an index if the SQL statement applies a function to the indexed column, unless it is a function-based index.

Pruning can eliminate index partitions even when the underlying table's partitions cannot be eliminated, but only when the index and table are partitioned on different columns. You can often improve the performance of operations on large tables by creating partitioned indexes that reduce the amount of data that your SQL statements need to access or modify.

Equality, range, LIKE, and IN-list predicates are considered for partition pruning with range or list partitioning, and equality and IN-list predicates are considered for partition pruning with hash partitioning.

Partition Pruning Example

We have a partitioned table called orders. The partition key for orders is order_date. Let's assume that orders has six months of data, January to June, with a partition for each month of data. If the following query is run:

SELECT SUM(value) 
FROM orders 
WHERE order_date BETWEEN '28-MAR-98' AND '23-APR-98'

Partition pruning is achieved by:

Partition-wise Joins

A partition-wise join is a join optimization that you can use when joining two tables that are both partitioned along the join column(s). With partition-wise joins, the join operation is broken into smaller joins that are performed sequentially or in parallel. Another way of looking at partition-wise joins is that they minimize the amount of data exchanged among parallel slaves during the execution of parallel joins by taking into account data distribution.

See Also:

Oracle9i Data Warehousing Guide for more information about partitioning methods and partition-wise joins

Parallel DML

Parallel execution dramatically reduces response time for data-intensive operations on large databases typically associated with decision support systems and data warehouses. In addition to conventional tables, you can use parallel query and parallel DML with range- and hash-partitioned tables. By doing so, you can enhance scalability and performance for batch operations.

The semantics and restrictions for parallel DML sessions are the same whether you are using index-organized tables or not.

See Also:

Oracle9i Data Warehousing Guide for more information about parallel DML and its use with partitioned tables


Go to previous page Go to next page
Oracle
Copyright © 1996, 2002 Oracle Corporation.

All Rights Reserved.
Go To Documentation Library
Home
Go To Product List
Book List
Go To Table Of Contents
Contents
Go To Index
Index

Master Index

Feedback