Use the INSERT
statement to add rows to a table, the base table of a view, a partition of a partitioned table or a subpartition of a composite-partitioned table, or an object table or the base table of an object view.
For you to insert rows into a table, the table must be in your own schema or you must have the INSERT
object privilege on the table.
For you to insert rows into the base table of a view, the owner of the schema containing the view must have the INSERT
object privilege on the base table. Also, if the view is in a schema other than your own, then you must have the INSERT
object privilege on the view.
If you have the INSERT
ANY
TABLE
system privilege, then you can also insert rows into any table or the base table of any view.
You must also have the READ
or SELECT
object privilege on the table into which you want to insert rows if the table is on a remote database.
Conventional and Direct-Path INSERT
You can use the INSERT
statement to insert data into a table, partition, or view in two ways: conventional INSERT
and direct-path INSERT
. When you issue a conventional INSERT
statement, Oracle Database reuses free space in the table into which you are inserting and maintains referential integrity constraints. With direct-path INSERT
, the database appends the inserted data after existing data in the table. Data is written directly into data files, bypassing the buffer cache. Free space in the existing data is not reused. This alternative enhances performance during insert operations and is similar to the functionality of the Oracle direct-path loader utility, SQL*Loader. When you insert into a table that has been created in parallel mode, direct-path INSERT
is the default.
The manner in which the database generates redo and undo data depends in part on whether you are using conventional or direct-path INSERT
:
Conventional INSERT
always generates maximal redo and undo for changes to both data and metadata, regardless of the logging setting of the table and the archivelog and force logging settings of the database.
Direct-path INSERT
generates both redo and undo for metadata changes, because these are needed for operation recovery. For data changes, undo and redo are generated as follows:
Direct-path INSERT
always bypasses undo generation for data changes.
If the database is not in ARCHIVELOG
or FORCE
LOGGING
mode, then no redo is generated for data changes, regardless of the logging setting of the table.
If the database is in ARCHIVELOG
mode (but not in FORCE
LOGGING
mode), then direct-path INSERT
generates data redo for LOGGING
tables but not for NOLOGGING
tables.
If the database is in ARCHIVELOG
and FORCE
LOGGING
mode, then direct-path SQL generate data redo for both LOGGING
and NOLOGGING
tables.
Direct-path INSERT
is subject to a number of restrictions. If any of these restrictions is violated, then Oracle Database executes conventional INSERT
serially without returning any message, unless otherwise noted:
You can have multiple direct-path INSERT
statements in a single transaction, with or without other DML statements. However, after one DML statement alters a particular table, partition, or index, no other DML statement in the transaction can access that table, partition, or index.
Queries that access the same table, partition, or index are allowed before the direct-path INSERT
statement, but not after it.
If any serial or parallel statement attempts to access a table that has already been modified by a direct-path INSERT
in the same transaction, then the database returns an error and rejects the statement.
The target table cannot be of a cluster.
The target table cannot contain object type columns.
Direct-path INSERT
is not supported for an index-organized table (IOT) if it has a mapping table, or if it is reference by a materialized view.
Direct-path INSERT
into a single partition of an index-organized table (IOT), into a partitioned IOT with only one partition, or into an IOT that is not partitioned, will be done serially, even if the IOT was created in parallel mode or you specify the APPEND
or APPEND_VALUES
hint. However, direct-path INSERT
operations into a partitioned IOT will honor parallel mode as long as the partition-extended name is not used and the IOT has more than one partition.
The target table cannot have any triggers or referential integrity constraints defined on it.
The target table cannot be replicated.
A transaction containing a direct-path INSERT
statement cannot be or become distributed.
You cannot query or modify direct-path inserted data immediately after the insert is complete. If you attempt to do so, an ORA-12838
error is generated. You must first issue a COMMIT
statement before attempting to read or modify the newly-inserted data.
See Also:
Oracle Database Administrator's Guide for a more complete description of direct-path INSERT
Oracle Database Utilities for information on SQL*Loader
Oracle Database SQL Tuning Guide for information on statistics gathering when inserting into an empty table using direct-path INSERT
(single_table_insert ::=, multi_table_insert ::=)
(insert_into_clause ::=, values_clause ::=, returning_clause::=, subquery::=, error_logging_clause ::=)
(DML_table_expression_clause::=)
values_clause ::=
(insert_into_clause ::=, values_clause ::=, conditional_insert_clause ::=, subquery::=, error_logging_clause ::=)
(insert_into_clause ::=, values_clause ::=)
DML_table_expression_clause::=
(partition_extension_clause::=, subquery::=—part of SELECT
, subquery_restriction_clause::=, table_collection_expression ::=)
subquery_restriction_clause::=
table_collection_expression ::=
Specify a comment that passes instructions to the optimizer on choosing an execution plan for the statement.
For a multitable insert, if you specify the PARALLEL
hint for any target table, then the entire multitable insert statement is parallelized even if the target tables have not been created or altered with PARALLEL
specified. If you do not specify the PARALLEL
hint, then the insert operation will not be parallelized unless all target tables were created or altered with PARALLEL
specified.
See Also:
"Hints" for the syntax and description of hints
In a single-table insert, you insert values into one row of a table, view, or materialized view by specifying values explicitly or by retrieving the values through a subquery.
You can use the flashback_query_clause
in subquery
to insert past data into table
. Refer to the flashback_query_clause of SELECT
for more information on this clause.
Restriction on Single-table Inserts If you retrieve values through a subquery, then the select list of the subquery must have the same number of columns as the column list of the INSERT
statement. If you omit the column list, then the subquery must provide values for every column in the table.
See Also:
"Inserting Values into Tables: Examples"Use the INSERT
INTO
clause to specify the target object or objects into which the database is to insert data.
Use the INTO
DML_table_expression_clause
to specify the objects into which data is being inserted.
schema Specify the schema containing the table, view, or materialized view. If you omit schema
, then the database assumes the object is in your own schema.
table | view | materialized_view | subquery Specify the name of the table or object table, view or object view, materialized view, or the column or columns returned by a subquery, into which rows are to be inserted. If you specify a view or object view, then the database inserts rows into the base table of the view.
You cannot insert rows into a read-only materialized view. If you insert rows into a writable materialized view, then the database inserts the rows into the underlying container table. However, the insertions are overwritten at the next refresh operation. If you insert rows into an updatable materialized view that is part of a materialized view group, then the database also inserts the corresponding rows into the master table.
If any value to be inserted is a REF
to an object table, and if the object table has a primary key object identifier, then the column into which you insert the REF
must be a REF
column with a referential integrity or SCOPE
constraint to the object table.
If table
, or the base table of view
, contains one or more domain index columns, then this statement executes the appropriate indextype insert routine.
Issuing an INSERT
statement against a table fires any INSERT
triggers defined on the table.
See Also:
Oracle Database Data Cartridge Developer's Guide for more information on these routinesRestrictions on the DML_table_expression_clause This clause is subject to the following restrictions:
You cannot execute this statement if table
or the base table of view
contains any domain indexes marked IN_PROGRESS
or FAILED
.
You cannot insert into a partition if any affected index partitions are marked UNUSABLE
.
With regard to the ORDER
BY
clause of the subquery
in the DML_table_expression_clause
, ordering is guaranteed only for the rows being inserted, and only within each extent of the table. Ordering of new rows with respect to existing rows is not guaranteed.
If a view was created using the WITH
CHECK
OPTION
, then you can insert into the view only rows that satisfy the defining query of the view.
If a view was created using a single base table, then you can insert rows into the view and then retrieve those values using the returning_clause
.
You cannot insert rows into a view except with INSTEAD
OF
triggers if the defining query of the view contains one of the following constructs:
DISTINCT
operatorGROUP
BY
, ORDER
BY
, MODEL
, CONNECT
BY
, or START
WITH
clauseSELECT
listSELECT
listWITH READ ONLY
If you specify an index, index partition, or index subpartition that has been marked UNUSABLE
, then the INSERT
statement will fail unless the SKIP_UNUSABLE_INDEXES
session parameter has been set to TRUE
. Refer to ALTER SESSION for information on the SKIP_UNUSABLE_INDEXES
session parameter.
partition_extension_clause Specify the name or partition key value of the partition or subpartition within table
, or the base table of view
, targeted for inserts.
If a row to be inserted does not map into a specified partition or subpartition, then the database returns an error.
Restriction on Target Partitions and Subpartitions This clause is not valid for object tables or object views.
dblink Specify a complete or partial name of a database link to a remote database where the table or view is located. You can insert rows into a remote table or view only if you are using Oracle Database distributed functionality.
If you omit dblink
, then Oracle Database assumes that the table or view is on the local database.
See Also:
"Syntax for Schema Objects and Parts in SQL Statements" and "References to Objects in Remote Databases" for information on referring to database links
subquery_restriction_clause Use the subquery_restriction_clause
to restrict the subquery in one of the following ways:
WITH READ ONLY Specify WITH READ ONLY
to indicate that the table or view cannot be updated.
WITH CHECK OPTION Specify WITH CHECK OPTION
to indicate that Oracle Database prohibits any changes to the table or view that would produce rows that are not included in the subquery. When used in the subquery of a DML statement, you can specify this clause in a subquery in the FROM
clause but not in subquery in the WHERE
clause.
CONSTRAINT constraint Specify the name of the CHECK OPTION
constraint. If you omit this identifier, then Oracle automatically assigns the constraint a name of the form SYS_C
n
, where n is an integer that makes the constraint name unique within the database.
The table_collection_expression
lets you inform Oracle that the value of collection_expression
should be treated as a table for purposes of query and DML operations. The collection_expression
can be a subquery, a column, a function, or a collection constructor. Regardless of its form, it must return a collection value—that is, a value whose type is nested table or varray. This process of extracting the elements of a collection is called collection unnesting.
The optional plus (+) is relevant if you are joining the TABLE
collection expression with the parent table. The + creates an outer join of the two, so that the query returns rows from the outer table even if the collection expression is null.
Note:
In earlier releases of Oracle, whencollection_expression
was a subquery, table_collection_expression
was expressed as THE
subquery
. That usage is now deprecated.See Also:
"Table Collections: Examples"Specify a correlation name, which is an alias for the table, view, materialized view, or subquery to be referenced elsewhere in the statement.
Restriction on Table Aliases You cannot specify t_alias
during a multitable insert.
Specify a column of the table, view, or materialized view. In the inserted row, each column in this list is assigned a value from the values_clause
or the subquery. If you want to assign a value to an INVISIBLE
column, then you must include the column in this list.
If you omit one or more of the table's columns from this list, then the column value of that column for the inserted row is the column default value as specified when the table was created or last altered. If any omitted column has a NOT
NULL
constraint and no default value, then the database returns an error indicating that the constraint has been violated and rolls back the INSERT
statement. Refer to CREATE TABLE for more information on default column values.
If you omit the column list altogether, then the values_clause
or query must specify values for all columns in the table.
For a single-table insert operation, specify a row of values to be inserted into the table or view. You must specify a value in the values_clause
for each column in the column list. If you omit the column list, then the values_clause
must provide values for every column in the table.
For a multitable insert operation, each expression in the values_clause
must refer to columns returned by the select list of the subquery. If you omit the values_clause
, then the select list of the subquery determines the values to be inserted, so it must have the same number of columns as the column list of the corresponding insert_into_clause
. If you do not specify a column list in the insert_into_clause
, then the computed row must provide values for all columns in the target table.
For both types of insert operations, if you specify a column list in the insert_into_clause
, then the database assigns to each column in the list a corresponding value from the values clause or the subquery. You can specify DEFAULT
for any value in the values_clause
. If you have specified a default value for the corresponding column of the table or view, then that value is inserted. If no default value for the corresponding column has been specified, then the database inserts null. Refer to "About SQL Expressions" and SELECT for syntax of valid expressions.
Restrictions on Inserted Values The value are subject to the following restrictions:
You cannot insert a BFILE
value until you have initialized the BFILE
locator to null or to a directory name and filename.
See Also:
BFILENAME for information on initializing BFILE
values and for an example of inserting into a BFILE
Oracle Database SecureFiles and Large Objects Developer's Guide for information on initializing BFILE
locators
When inserting into a list-partitioned table, you cannot insert a value into the partitioning key column that does not already exist in the partition_key_value
list of one of the partitions.
You cannot specify DEFAULT
when inserting into a view.
If you insert string literals into a RAW
column, then during subsequent queries Oracle Database will perform a full table scan rather than using any index that might exist on the RAW
column.
See Also:
"Using XML in SQL Statements" for information on inserting values into an XMLType table
"Inserting into a Substitutable Tables and Columns: Examples", "Inserting Using the TO_LOB Function: Example", "Inserting Sequence Values: Example", and "Inserting Using Bind Variables: Example"
The returning clause retrieves the rows affected by a DML statement. You can specify this clause for tables and materialized views and for views with a single base table.
When operating on a single row, a DML statement with a returning_clause
can retrieve column expressions using the affected row, rowid, and REFs
to the affected row and store them in host variables or PL/SQL variables.
When operating on multiple rows, a DML statement with the returning_clause
stores values from expressions, rowids, and REFs
involving the affected rows in bind arrays.
expr Each item in the expr
list must be a valid expression syntax.
INTO The INTO
clause indicates that the values of the changed rows are to be stored in the variable(s) specified in data_item
list.
data_item Each data_item
is a host variable or PL/SQL variable that stores the retrieved expr
value.
For each expression in the RETURNING
list, you must specify a corresponding type-compatible PL/SQL variable or host variable in the INTO
list.
Restrictions The following restrictions apply to the RETURNING
clause:
The expr
is restricted as follows:
For UPDATE
and DELETE
statements each expr
must be a simple expression or a single-set aggregate function expression. You cannot combine simple expressions and single-set aggregate function expressions in the same returning_clause
. For INSERT
statements, each expr
must be a simple expression. Aggregate functions are not supported in an INSERT
statement RETURNING
clause.
Single-set aggregate function expressions cannot include the DISTINCT
keyword.
If the expr
list contains a primary key column or other NOT
NULL
column, then the update statement fails if the table has a BEFORE
UPDATE
trigger defined on it.
You cannot specify the returning_clause
for a multitable insert.
You cannot use this clause with parallel DML or with remote objects.
You cannot retrieve LONG
types with this clause.
You cannot specify this clause for a view on which an INSTEAD
OF
trigger has been defined.
See Also:
Oracle Database PL/SQL Language Reference for information on using theBULK
COLLECT
clause to return multiple values to collection variablesIn a multitable insert, you insert computed rows derived from the rows returned from the evaluation of a subquery into one or more tables.
Table aliases are not defined by the select list of the subquery. Therefore, they are not visible in the clauses dependent on the select list. For example, this can happen when trying to refer to an object column in an expression. To use an expression with a table alias, you must put the expression into the select list with a column alias, and then refer to the column alias in the VALUES
clause or WHEN
condition of the multitable insert.
Specify ALL
followed by multiple insert_into_clauses
to perform an unconditional multitable insert. Oracle Database executes each insert_into_clause
once for each row returned by the subquery.
Specify the conditional_insert_clause
to perform a conditional multitable insert. Oracle Database filters each insert_into_clause
through the corresponding WHEN
condition, which determines whether that insert_into_clause
is executed. Each expression in the WHEN
condition must refer to columns returned by the select list of the subquery. A single multitable insert statement can contain up to 127 WHEN
clauses.
ALL If you specify ALL
, the default value, then the database evaluates each WHEN
clause regardless of the results of the evaluation of any other WHEN
clause. For each WHEN
clause whose condition evaluates to true, the database executes the corresponding INTO
clause list.
FIRST If you specify FIRST
, then the database evaluates each WHEN
clause in the order in which it appears in the statement. For the first WHEN
clause that evaluates to true, the database executes the corresponding INTO
clause and skips subsequent WHEN
clauses for the given row.
ELSE clause For a given row, if no WHEN
clause evaluates to true, then:
If you have specified an ELSE
clause, then the database executes the INTO
clause list associated with the ELSE
clause.
If you did not specify an else clause, then the database takes no action for that row.
See Also:
"Multitable Inserts: Examples"Restrictions on Multitable Inserts Multitable inserts are subject to the following restrictions:
You can perform multitable inserts only on tables, not on views or materialized views.
You cannot perform a multitable insert into a remote table.
You cannot specify a TABLE
collection expression when performing a multitable insert.
Multitable inserts are not parallelized if any target table is index organized or if any target table has a bitmap index defined on it.
Plan stability is not supported for multitable insert statements.
You cannot specify a sequence in any part of a multitable insert statement. A multitable insert is considered a single SQL statement. Therefore, the first reference to NEXTVAL
generates the next number, and all subsequent references in the statement return the same number.
Specify a subquery that returns rows that are inserted into the table. The subquery can refer to any table, view, or materialized view, including the target tables of the INSERT
statement. If the subquery selects no rows, then the database inserts no rows into the table.
You can use subquery
in combination with the TO_LOB
function to convert the values in a LONG
column to LOB values in another column in the same or another table.
To migrate LONG
values to LOB values in another column in a view, you must perform the migration on the base table and then add the LOB column to the view.
To migrate LONG
values on a remote table to LOB values in a local table, you must perform the migration on the remote table using the TO_LOB
function, and then perform an INSERT
... subquery
operation to copy the LOB values from the remote table into the local table.
Notes on Inserting with a Subquery The following notes apply when inserting with a subquery:
If subquery
returns the partial or total equivalent of a materialized view, then the database may use the materialized view for query rewrite in place of one or more tables specified in subquery
.
See Also:
Oracle Database Data Warehousing Guide for more information on materialized views and query rewriteIf subquery
refers to remote objects, then the INSERT
operation can run in parallel as long as the reference does not loop back to an object on the local database. However, if the subquery
in the DML_table_expression_clause
refers to any remote objects, then the INSERT
operation will run serially without notification. See parallel_clause for more information.
If subquery
includes an ORDER
BY
clause, then it will override row ordering specified using attribute clustering table properties.
See Also:
BFILENAME for an example of inserting into a BFILE
Oracle Database SecureFiles and Large Objects Developer's Guide for information on initializing BFILE
s
"About SQL Expressions" and SELECT for syntax of valid expressions
The error_logging_clause
lets you capture DML errors and the log column values of the affected rows and save them in an error logging table.
INTO table Specify the name of the error logging table. If you omit this clause, then the database assigns the default name generated by the DBMS_ERRLOG
package. The default error log table name is ERR$_
followed by the first 25 characters of the name of the table upon which the DML operation is being executed.
simple_expression Specify the value to be used as a statement tag, so that you can identify the errors from this statement in the error logging table. The expression can be either a text literal, a number literal, or a general SQL expression such as a bind variable. You can also use a function expression if you convert it to a text literal — for example, TO_CHAR(SYSDATE)
.
REJECT LIMIT This clause lets you specify an integer as an upper limit for the number of errors to be logged before the statement terminates and rolls back any changes made by the statement. The default rejection limit is zero. For parallel DML operations, the reject limit is applied to each parallel server.
Restrictions on DML Error Logging
The following conditions cause the statement to fail and roll back without invoking the error logging capability:
Violated deferred constraints.
Any direct-path INSERT
or MERGE
operation that raises a unique constraint or index violation.
Any update operation UPDATE
or MERGE
that raises a unique constraint or index violation.
You cannot track errors in the error logging table for LONG
, LOB, or object type columns. However, the table that is the target of the DML operation can contain these types of columns.
If you create or modify the corresponding error logging table so that it contains a column of an unsupported type, and if the name of that column corresponds to an unsupported column in the target DML table, then the DML statement fails at parse time.
If the error logging table does not contain any unsupported column types, then all DML errors are logged until the reject limit of errors is reached. For rows on which errors occur, column values with corresponding columns in the error logging table are logged along with the control information.
See Also:
Oracle Database PL/SQL Packages and Types Reference for information on using the create_error_log
procedure of the DBMS_ERRLOG
package and Oracle Database Administrator's Guide for general information on DML error logging.
Inserting Values into Tables: Examples The following statement inserts a row into the sample table departments
:
INSERT INTO departments VALUES (280, 'Recreation', 121, 1700);
If the departments
table had been created with a default value of 121 for the manager_id
column, then you could issue the same statement as follows:
INSERT INTO departments VALUES (280, 'Recreation', DEFAULT, 1700);
The following statement inserts a row with six columns into the employees
table. One of these columns is assigned NULL
and another is assigned a number in scientific notation:
INSERT INTO employees (employee_id, last_name, email, hire_date, job_id, salary, commission_pct) VALUES (207, 'Gregory', 'pgregory@example.com', sysdate, 'PU_CLERK', 1.2E3, NULL);
The following statement has the same effect as the preceding example, but uses a subquery in the DML_table_expression_clause
:
INSERT INTO (SELECT employee_id, last_name, email, hire_date, job_id, salary, commission_pct FROM employees) VALUES (207, 'Gregory', 'pgregory@example.com', sysdate, 'PU_CLERK', 1.2E3, NULL);
Inserting Values with a Subquery: Example The following statement copies employees whose commission exceeds 25% of their salary into the bonuses
table, which was created in "Merging into a Table: Example":
INSERT INTO bonuses SELECT employee_id, salary*1.1 FROM employees WHERE commission_pct > 0.25;
Inserting Into a Table with Error Logging: Example The following statements create a raises
table in the sample schema hr
, create an error logging table using the DBMS_ERRLOG
package, and populate the raises
table with data from the employees
table. One of the inserts violates the check constraint on raises
, and that row can be seen in errlog
. If more than ten errors had occurred, then the statement would have aborted, rolling back any insertions made:
CREATE TABLE raises (emp_id NUMBER, sal NUMBER CONSTRAINT check_sal CHECK(sal > 8000)); EXECUTE DBMS_ERRLOG.CREATE_ERROR_LOG('raises', 'errlog');
INSERT INTO raises SELECT employee_id, salary*1.1 FROM employees WHERE commission_pct > .2 LOG ERRORS INTO errlog ('my_bad') REJECT LIMIT 10; SELECT ORA_ERR_MESG$, ORA_ERR_TAG$, emp_id, sal FROM errlog; ORA_ERR_MESG$ ORA_ERR_TAG$ EMP_ID SAL --------------------------- -------------------- ------ ------- ORA-02290: check constraint my_bad 161 7700 (HR.SYS_C004266) violated
Inserting into a Remote Database: Example The following statement inserts a row into the employees
table owned by the user hr
on the database accessible by the database link remote
:
INSERT INTO employees@remote VALUES (8002, 'Juan', 'Fernandez', 'juanf@example.com', NULL, TO_DATE('04-OCT-1992', 'DD-MON-YYYY'), 'SH_CLERK', 3000, NULL, 121, 20);
Inserting Sequence Values: Example The following statement inserts a new row containing the next value of the departments_seq
sequence into the departments
table:
INSERT INTO departments VALUES (departments_seq.nextval, 'Entertainment', 162, 1400);
Inserting Using Bind Variables: Example The following example returns the values of the inserted rows into output bind variables :bnd1
and :bnd2
. The bind variables must first be declared.
INSERT INTO employees (employee_id, last_name, email, hire_date, job_id, salary) VALUES (employees_seq.nextval, 'Doe', 'john.doe@example.com', SYSDATE, 'SH_CLERK', 2400) RETURNING salary*12, job_id INTO :bnd1, :bnd2;
Inserting into a Substitutable Tables and Columns: Examples The following example inserts into the persons
table, which is created in "Substitutable Table and Column Examples". The first statement uses the root type person_t
. The second insert uses the employee_t
subtype of person_t
, and the third insert uses the part_time_emp_t
subtype of employee_t
:
INSERT INTO persons VALUES (person_t('Bob', 1234)); INSERT INTO persons VALUES (employee_t('Joe', 32456, 12, 100000)); INSERT INTO persons VALUES ( part_time_emp_t('Tim', 5678, 13, 1000, 20));
The following example inserts into the books
table, which was created in "Substitutable Table and Column Examples". Notice that specification of the attribute values is identical to that for the substitutable table example:
INSERT INTO books VALUES ( 'An Autobiography', person_t('Bob', 1234)); INSERT INTO books VALUES ( 'Business Rules', employee_t('Joe', 3456, 12, 10000)); INSERT INTO books VALUES ( 'Mixing School and Work', part_time_emp_t('Tim', 5678, 13, 1000, 20));
You can extract data from substitutable tables and columns using built-in functions and conditions. For examples, see the functions TREAT and SYS_TYPEID, and "IS OF type Condition".
Inserting Using the TO_LOB Function: Example The following example copies LONG
data to a LOB column in the following long_tab
table:
CREATE TABLE long_tab (pic_id NUMBER, long_pics LONG RAW);
First you must create a table with a LOB.
CREATE TABLE lob_tab (pic_id NUMBER, lob_pics BLOB);
Next, use an INSERT
... SELECT
statement to copy the data in all rows for the LONG
column into the newly created LOB column:
INSERT INTO lob_tab SELECT pic_id, TO_LOB(long_pics) FROM long_tab;
When you are confident that the migration has been successful, you can drop the long_pics
table. Alternatively, if the table contains other columns, then you can simply drop the LONG
column from the table as follows:
ALTER TABLE long_tab DROP COLUMN long_pics;
Multitable Inserts: Examples The following example uses the multitable insert syntax to insert into the sample table sh.sales
some data from an input table with a different structure.
Note:
A number ofNOT
NULL
constraints on the sales
table have been disabled for purposes of this example, because the example ignores a number of table columns for the sake of brevity.The input table looks like this:
SELECT * FROM sales_input_table; PRODUCT_ID CUSTOMER_ID WEEKLY_ST SALES_SUN SALES_MON SALES_TUE SALES_WED SALES_THU SALES_FRI SALES_SAT ---------- ----------- --------- ---------- ---------- ---------- -------------------- ---------- ---------- 111 222 01-OCT-00 100 200 300 400 500 600 700 222 333 08-OCT-00 200 300 400 500 600 700 800 333 444 15-OCT-00 300 400 500 600 700 800 900
The multitable insert statement looks like this:
INSERT ALL INTO sales (prod_id, cust_id, time_id, amount) VALUES (product_id, customer_id, weekly_start_date, sales_sun) INTO sales (prod_id, cust_id, time_id, amount) VALUES (product_id, customer_id, weekly_start_date+1, sales_mon) INTO sales (prod_id, cust_id, time_id, amount) VALUES (product_id, customer_id, weekly_start_date+2, sales_tue) INTO sales (prod_id, cust_id, time_id, amount) VALUES (product_id, customer_id, weekly_start_date+3, sales_wed) INTO sales (prod_id, cust_id, time_id, amount) VALUES (product_id, customer_id, weekly_start_date+4, sales_thu) INTO sales (prod_id, cust_id, time_id, amount) VALUES (product_id, customer_id, weekly_start_date+5, sales_fri) INTO sales (prod_id, cust_id, time_id, amount) VALUES (product_id, customer_id, weekly_start_date+6, sales_sat) SELECT product_id, customer_id, weekly_start_date, sales_sun, sales_mon, sales_tue, sales_wed, sales_thu, sales_fri, sales_sat FROM sales_input_table;
Assuming these are the only rows in the sales
table, the contents now look like this:
SELECT * FROM sales ORDER BY prod_id, cust_id, time_id; PROD_ID CUST_ID TIME_ID C PROMO_ID QUANTITY_SOLD AMOUNT COST ---------- ---------- --------- - ---------- ------------- ---------- ---------- 111 222 01-OCT-00 100 111 222 02-OCT-00 200 111 222 03-OCT-00 300 111 222 04-OCT-00 400 111 222 05-OCT-00 500 111 222 06-OCT-00 600 111 222 07-OCT-00 700 222 333 08-OCT-00 200 222 333 09-OCT-00 300 222 333 10-OCT-00 400 222 333 11-OCT-00 500 222 333 12-OCT-00 600 222 333 13-OCT-00 700 222 333 14-OCT-00 800 333 444 15-OCT-00 300 333 444 16-OCT-00 400 333 444 17-OCT-00 500 333 444 18-OCT-00 600 333 444 19-OCT-00 700 333 444 20-OCT-00 800 333 444 21-OCT-00 900
The next examples insert into multiple tables. Suppose you want to provide to sales representatives some information on orders of various sizes. The following example creates tables for small, medium, large, and special orders and populates those tables with data from the sample table oe.orders
:
CREATE TABLE small_orders (order_id NUMBER(12) NOT NULL, customer_id NUMBER(6) NOT NULL, order_total NUMBER(8,2), sales_rep_id NUMBER(6) ); CREATE TABLE medium_orders AS SELECT * FROM small_orders; CREATE TABLE large_orders AS SELECT * FROM small_orders; CREATE TABLE special_orders (order_id NUMBER(12) NOT NULL, customer_id NUMBER(6) NOT NULL, order_total NUMBER(8,2), sales_rep_id NUMBER(6), credit_limit NUMBER(9,2), cust_email VARCHAR2(40) );
The first multitable insert populates only the tables for small, medium, and large orders:
INSERT ALL WHEN order_total <= 100000 THEN INTO small_orders WHEN order_total > 1000000 AND order_total <= 200000 THEN INTO medium_orders WHEN order_total > 200000 THEN INTO large_orders SELECT order_id, order_total, sales_rep_id, customer_id FROM orders;
You can accomplish the same thing using the ELSE
clause in place of the insert into the large_orders
table:
INSERT ALL WHEN order_total <= 100000 THEN INTO small_orders WHEN order_total > 100000 AND order_total <= 200000 THEN INTO medium_orders ELSE INTO large_orders SELECT order_id, order_total, sales_rep_id, customer_id FROM orders;
The next example inserts into the small, medium, and large tables, as in the preceding example, and also puts orders greater than 290,000 into the special_orders
table. This table also shows how to use column aliases to simplify the statement:
INSERT ALL WHEN ottl <= 100000 THEN INTO small_orders VALUES(oid, ottl, sid, cid) WHEN ottl > 100000 and ottl <= 200000 THEN INTO medium_orders VALUES(oid, ottl, sid, cid) WHEN ottl > 200000 THEN into large_orders VALUES(oid, ottl, sid, cid) WHEN ottl > 290000 THEN INTO special_orders SELECT o.order_id oid, o.customer_id cid, o.order_total ottl, o.sales_rep_id sid, c.credit_limit cl, c.cust_email cem FROM orders o, customers c WHERE o.customer_id = c.customer_id;
Finally, the next example uses the FIRST
clause to put orders greater than 290,000 into the special_orders
table and exclude those orders from the large_orders
table:
INSERT FIRST WHEN ottl <= 100000 THEN INTO small_orders VALUES(oid, ottl, sid, cid) WHEN ottl > 100000 and ottl <= 200000 THEN INTO medium_orders VALUES(oid, ottl, sid, cid) WHEN ottl > 290000 THEN INTO special_orders WHEN ottl > 200000 THEN INTO large_orders VALUES(oid, ottl, sid, cid) SELECT o.order_id oid, o.customer_id cid, o.order_total ottl, o.sales_rep_id sid, c.credit_limit cl, c.cust_email cem FROM orders o, customers c WHERE o.customer_id = c.customer_id;